GS2220 Series
- Contents Overview
- Table of Contents
User’s Guide
Technical Reference
Troubleshooting and Appendices

Zyxel GS2220-10-EU0101F User Manual

Displayed below is the user manual for GS2220-10-EU0101F by Zyxel which is a product in the Network Switches category. This manual has pages.

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Default Login Details

User’s Guide

GS2220 Series

8/24/44-Port GbE L2 Switch with 2/4 Dual Personality GbE Uplinks

8/24/44-Port GbE L2 PoE Switch with 2/4 Dual Personality GbE Uplinks

Management IP

Address

http://DHCP-assigned IP

http://192.168.1.1

User Name admin

Password 1234

Version 4.60 Edition 1, 11/2019

GS2220 Series User’s Guide

IMPORTANT!

READ CAREFULLY BEFORE USE.

KEEP THIS GUIDE FOR FUTURE REFERENCE.

Screenshots and graphics in this book may differ slightly from your product due to differences in your

product firmware or your computer operating system. Every effort has been made to ensure that the

information in this manual is accurate.

Related Documentation

•CLI Reference Guide

This guide explains how to use the Command-Line Interface (CLI) to configure the Switch.

Note: It is recommended you use the Web Configurator to configure the Switch.

• Web Configurator Online Help

Click the help icon in any screen for help in configuring that screen and supplementary information.

•More Information

Go to https://businessforum.zyxel.com for product discussions.

Go to support.zyxel.com to find other information on the Switch.

Contents Overview

GS2220 Series User’s Guide

Contents Overview

User’s Guide ......................................................................................................................................20

Getting to Know Your Switch .............................................................................................................. 21

Hardware Installation and Connection ............................................................................................. 30

Hardware Overview ............................................................................................................................. 35

The Web Configurator ......................................................................................................................... 43

Initial Setup Example ............................................................................................................................ 59

Tutorials .................................................................................................................................................. 63

Technical Reference ........................................................................................................................73

Status ...................................................................................................................................................... 74

Basic Setting .......................................................................................................................................... 80

VLAN .................................................................................................................................................... 110

Static MAC Forward Setup ................................................................................................................ 131

Static Multicast Forwarding ............................................................................................................... 133

Filtering ................................................................................................................................................. 136

Spanning Tree Protocol ...................................................................................................................... 138

Bandwidth Control ............................................................................................................................. 159

Broadcast Storm Control ................................................................................................................... 161

Mirroring ............................................................................................................................................... 163

Link Aggregation ................................................................................................................................ 165

Port Authentication ............................................................................................................................ 172

Port Security ......................................................................................................................................... 181

Time Range ......................................................................................................................................... 183

Classifier ............................................................................................................................................... 185

Policy Rule ........................................................................................................................................... 194

Queuing Method ................................................................................................................................ 198

Multicast .............................................................................................................................................. 201

AAA ...................................................................................................................................................... 224

IP Source Guard .................................................................................................................................. 237

Loop Guard ......................................................................................................................................... 267

VLAN Mapping ................................................................................................................................... 270

Layer 2 Protocol Tunneling ................................................................................................................ 273

PPPoE ................................................................................................................................................... 277

Error Disable ......................................................................................................................................... 285

Private VLAN ....................................................................................................................................... 291

Green Ethernet ................................................................................................................................... 293

Link Layer Discovery Protocol (LLDP) ................................................................................................ 295

Anti-Arpscan ....................................................................................................................................... 317

Contents Overview

GS2220 Series User’s Guide

BPDU Guard ........................................................................................................................................ 322

OAM ..................................................................................................................................................... 325

ZULD ...................................................................................................................................................... 332

Static Route ......................................................................................................................................... 336

Differentiated Services ....................................................................................................................... 339

DHCP .................................................................................................................................................... 343

ARP Setup ............................................................................................................................................ 354

Maintenance ...................................................................................................................................... 358

Access Control .................................................................................................................................... 372

Diagnostic ........................................................................................................................................... 392

System Log .......................................................................................................................................... 394

Syslog Setup ........................................................................................................................................ 395

Cluster Management ......................................................................................................................... 398

MAC Table ........................................................................................................................................... 404

ARP Table ............................................................................................................................................ 407

Path MTU Table ................................................................................................................................... 409

Configure Clone ................................................................................................................................. 410

IPv6 Neighbor Table ........................................................................................................................... 413

Port Status ............................................................................................................................................ 415

Troubleshooting and Appendices .................................................................................................422

Troubleshooting .................................................................................................................................. 423

Table of Contents

GS2220 Series User’s Guide

Table of Contents

Contents Overview .............................................................................................................................3

Table of Contents.................................................................................................................................5

Part I: User’s Guide..........................................................................................20

Chapter 1

Getting to Know Your Switch ............................................................................................................21

1.1 Introduction ..................................................................................................................................... 21

1.1.1 Management Method ......................................................................................................... 22

1.1.2 Management Modes ........................................................................................................... 22

1.1.3 Mode Changing ................................................................................................................... 23

1.1.4 ZON Utility ............................................................................................................................... 24

1.1.5 PoE .......................................................................................................................................... 24

1.2 Example Applications .................................................................................................................... 25

1.2.1 PoE Example Application ..................................................................................................... 25

1.2.2 Backbone Example Application ......................................................................................... 26

1.2.3 Bridging/Fiber Uplink Example Application ........................................................................ 26

1.2.4 High Performance Switching Example ............................................................................... 27

1.2.5 IEEE 802.1Q VLAN Application Example ............................................................................. 27

1.2.6 IPv6 Support ........................................................................................................................... 28

1.3 Ways to Manage the Switch ......................................................................................................... 28

1.4 Good Habits for Managing the Switch ........................................................................................29

Chapter 2

Hardware Installation and Connection ...........................................................................................30

2.1 Installation Scenarios ...................................................................................................................... 30

2.2 Desktop Installation Procedure .................................................................................................... 30

2.3 Mounting the Switch on a Rack .................................................................................................. 31

2.3.1 Installation Requirements ..................................................................................................... 31

2.3.2 Attaching the Mounting Brackets to the Switch ............................................................... 32

2.3.3 Mounting the Switch on a Rack .......................................................................................... 32

2.4 Wall Mounting (GS2220-10 and GS2220-10HP Only) .................................................................. 33

2.4.1 Installation Requirement ...................................................................................................... 33

Chapter 3

Hardware Overview...........................................................................................................................35

3.1 Front Panel Connections .............................................................................................................. 35

Table of Contents

GS2220 Series User’s Guide

3.1.1 SFP Slots ................................................................................................................................. 36

3.1.2 Ethernet Ports ......................................................................................................................... 38

3.1.3 PoE (GS2220-10HP, GS2220-28HP and GS2220-50HP) ....................................................... 38

3.1.4 Dual Personality Interfaces .................................................................................................. 38

3.1.5 Console Port ......................................................................................................................... 39

3.2 Rear Panel ....................................................................................................................................... 39

3.2.1 Grounding .............................................................................................................................. 40

3.2.2 AC Power Connection ......................................................................................................... 40

3.3 LEDs .............................................................................................................................................. 41

Chapter 4

The Web Configurator........................................................................................................................43

4.1 Overview ......................................................................................................................................... 43

4.2 System Login ............................................................................................................................... 43

4.3 Zyxel One Network (ZON) Utility ................................................................................................... 46

4.3.1 Requirements ......................................................................................................................... 46

4.3.2 Run the ZON Utility ................................................................................................................. 47

4.4 The Web Configurator Layout ...................................................................................................... 51

4.4.1 Change Your Password ..................................................................................................... 55

4.5 Saving Your Configuration ............................................................................................................. 56

4.6 Switch Lockout .............................................................................................................................. 56

4.7 Resetting the Switch .................................................................................................................... 56

4.7.1 Using the RESTORE Button ..................................................................................................... 56

4.7.2 Reload the Configuration File ............................................................................................. 57

4.8 Logging Out of the Web Configurator .......................................................................................57

4.9 Help ................................................................................................................................................. 58

Chapter 5

Initial Setup Example.........................................................................................................................59

5.1 Overview ......................................................................................................................................... 59

5.1.1 Creating a VLAN ................................................................................................................... 59

5.1.2 Setting Port VID ...................................................................................................................... 60

5.1.3 Configuring Switch Management IP Address .................................................................... 61

Chapter 6

Tutorials ...............................................................................................................................................63

6.1 Overview ......................................................................................................................................... 63

6.2 How to Use DHCPv4 Snooping on the Switch ............................................................................. 63

6.3 How to Use DHCPv4 Relay on the Switch .................................................................................... 66

6.3.1 DHCP Relay Tutorial Introduction ........................................................................................ 67

6.3.2 Creating a VLAN ................................................................................................................... 67

6.3.3 Configuring DHCPv4 Relay .................................................................................................. 69

6.3.4 Troubleshooting ..................................................................................................................... 70

Table of Contents

GS2220 Series User’s Guide

6.4 How to Use Auto Configuration via a DHCP Server on the Switch ........................................... 70

Part II: Technical Reference...........................................................................73

Chapter 7

Status...................................................................................................................................................74

7.1 Overview ......................................................................................................................................... 74

7.1.1 What You Can Do ................................................................................................................. 74

7.2 Status ............................................................................................................................................... 74

7.2.1 Neighbor Screen .................................................................................................................. 76

7.2.2 Neighbor Detail ..................................................................................................................... 77

Chapter 8

Basic Setting .......................................................................................................................................80

8.1 Overview ......................................................................................................................................... 80

8.1.1 What You Can Do ................................................................................................................. 80

8.2 System Information ...................................................................................................................... 80

8.3 General Setup ............................................................................................................................... 82

8.4 Introduction to VLANs ................................................................................................................... 84

8.5 Switch Setup ................................................................................................................................... 85

8.6 IP Setup ........................................................................................................................................... 86

8.6.1 Management IP Addresses ..................................................................................................86

8.7 Port Setup ....................................................................................................................................... 88

8.8 PoE Setup ........................................................................................................................................ 90

8.8.1 PoE Time Range Setup ......................................................................................................... 92

8.8.2 PoE Setup .............................................................................................................................. 93

8.9 Interface Setup ............................................................................................................................... 96

8.10 IPv6 ................................................................................................................................................. 97

8.10.1 IPv6 Interface Status ........................................................................................................... 97

8.10.2 IPv6 Configuration .............................................................................................................. 99

8.10.3 IPv6 Global Setup .............................................................................................................. 100

8.10.4 IPv6 Interface Setup .......................................................................................................... 101

8.10.5 IPv6 Link-Local Address Setup .......................................................................................... 102

8.10.6 IPv6 Global Address Setup ...............................................................................................103

8.10.7 IPv6 Neighbor Discovery Setup ....................................................................................... 103

8.10.8 IPv6 Neighbor Setup ......................................................................................................... 104

8.10.9 DHCPv6 Client Setup ........................................................................................................ 106

8.11 DNS ............................................................................................................................................... 107

8.12 Cloud Management .................................................................................................................. 107

8.12.1 Nebula Control Center Discovery ................................................................................... 108

8.12.2 Nebula Switch Registration ..............................................................................................108

Table of Contents

GS2220 Series User’s Guide

Chapter 9

VLAN..................................................................................................................................................110

9.1 Overview ....................................................................................................................................... 110

9.1.1 What You Can Do ............................................................................................................... 110

9.1.2 What You Need to Know ................................................................................................... 111

9.2 VLAN Status .................................................................................................................................. 114

9.2.1 VLAN Detail .......................................................................................................................... 115

9.3 VLAN Configuration .................................................................................................................... 115

9.4 Configure a Static VLAN ............................................................................................................ 116

9.5 Configure VLAN Port Setting ...................................................................................................... 118

9.6 Subnet Based VLANs .................................................................................................................... 119

9.6.1 Configuring Subnet Based VLAN ....................................................................................... 120

9.7 Protocol Based VLANs .................................................................................................................. 121

9.7.1 Configuring Protocol Based VLAN .................................................................................... 122

9.8 Voice VLAN Setup ........................................................................................................................ 123

9.9 MAC Based VLAN ......................................................................................................................... 125

9.10 Vendor ID Based VLAN .............................................................................................................. 126

9.11 Port-Based VLAN Setup ............................................................................................................. 128

9.11.1 Configure a Port Based VLAN ......................................................................................... 128

Chapter 10

Static MAC Forward Setup ..............................................................................................................131

10.1 Overview ..................................................................................................................................... 131

10.1.1 What You Can Do ............................................................................................................. 131

10.2 Configuring Static MAC Forwarding ....................................................................................... 131

Chapter 11

Static Multicast Forwarding.............................................................................................................133

11.1 Static Multicast Forward Setup Overview ............................................................................... 133

11.1.1 What You Can Do ............................................................................................................. 133

11.1.2 What You Need To Know ................................................................................................. 133

11.2 Configuring Static Multicast Forwarding .................................................................................. 134

Chapter 12

Filtering..............................................................................................................................................136

12.1 Filtering Overview ...................................................................................................................... 136

12.1.1 What You Can Do ............................................................................................................. 136

12.2 Configure a Filtering Rule .......................................................................................................... 136

Chapter 13

Spanning Tree Protocol ...................................................................................................................138

13.1 Spanning Tree Protocol Overview ........................................................................................... 138

13.1.1 What You Can Do ............................................................................................................. 138

Table of Contents

GS2220 Series User’s Guide

13.1.2 What You Need to Know ................................................................................................. 138

13.2 Spanning Tree Protocol Status Screen ..................................................................................... 141

13.3 Spanning Tree Configuration ................................................................................................... 142

13.4 Configure Rapid Spanning Tree Protocol ............................................................................. 142

13.5 Rapid Spanning Tree Protocol Status ......................................................................................144

13.6 Configure Multiple Spanning Tree Protocol ......................................................................... 146

13.6.1 Multiple Spanning Tree Protocol Port Configuration .................................................... 149

13.7 Multiple Spanning Tree Protocol Status ...................................................................................150

13.8 Configure Multiple Rapid Spanning Tree Protocol ................................................................. 153

13.9 Multiple Rapid Spanning Tree Protocol Status ........................................................................ 155

13.10 Technical Reference ................................................................................................................ 156

13.10.1 MSTP Network Example .................................................................................................. 156

13.10.2 MST Region ....................................................................................................................... 157

13.10.3 MST Instance .................................................................................................................... 157

13.10.4 Common and Internal Spanning Tree (CIST) ............................................................... 158

Chapter 14

Bandwidth Control ...........................................................................................................................159

14.1 Bandwidth Control Overview ................................................................................................... 159

14.1.1 What You Can Do ............................................................................................................. 159

14.2 Bandwidth Control Setup .......................................................................................................... 159

Chapter 15

Broadcast Storm Control .................................................................................................................161

15.1 Broadcast Storm Control Overview .........................................................................................161

15.1.1 What You Can Do ............................................................................................................. 161

15.2 Broadcast Storm Control Setup ................................................................................................ 161

Chapter 16

Mirroring............................................................................................................................................163

16.1 Mirroring Overview .................................................................................................................... 163

16.1.1 What You Can Do ............................................................................................................. 163

16.2 Port Mirroring Setup .................................................................................................................... 163

Chapter 17

Link Aggregation .......... .... .... .... .................. .... ... .... .................. .... .... ... ................... .... ... .... ...............165

17.1 Link Aggregation Overview ...................................................................................................... 165

17.1.1 What You Can Do ............................................................................................................. 165

17.1.2 What You Need to Know ................................................................................................. 165

17.2 Link Aggregation Status ............................................................................................................. 166

17.3 Link Aggregation Setting .......................................................................................................... 167

17.3.1 Link Aggregation Control Protocol .............................................................................. 169

17.4 Technical Reference .................................................................................................................. 170

Table of Contents

GS2220 Series User’s Guide

17.4.1 Static Trunking Example ................................................................................................... 170

Chapter 18

Port Authentication ..........................................................................................................................172

18.1 Port Authentication Overview ................................................................................................. 172

18.1.1 What You Can Do ............................................................................................................. 172

18.1.2 What You Need to Know ................................................................................................. 172

18.1.3 MAC Authentication ........................................................................................................ 173

18.2 Port Authentication Configuration ........................................................................................... 174

18.3 Activate IEEE 802.1x Security ................................................................................................... 174

18.3.1 Guest VLAN ....................................................................................................................... 176

18.4 Activate MAC Authentication ................................................................................................. 178

Chapter 19

Port Security......................................................................................................................................181

19.1 Port Security Overview .............................................................................................................. 181

19.1.1 What You Can Do ............................................................................................................. 181

19.2 Port Security Setup ...................................................................................................................... 181

Chapter 20

Time Range.......................................................................................................................................183

20.1 Time Range Overview ............................................................................................................... 183

20.1.1 What You Can Do ............................................................................................................. 183

20.2 Configuring Time Range ............................................................................................................ 183

Chapter 21

Classifier............................................................................................................................................185

21.1 Classifier Overview ..................................................................................................................... 185

21.1.1 What You Can Do ............................................................................................................. 185

21.1.2 What You Need to Know ................................................................................................. 185

21.2 Classifier Status ............................................................................................................................ 185

21.3 Classifier Configuration ............................................................................................................. 186

21.3.1 Viewing and Editing Classifier Configuration Summary ............................................... 190

21.4 Classifier Global Setting Configuration ................................................................................... 191

21.5 Classifier Example ....................................................................................................................... 192

Chapter 22

Policy Rule ........................................................................................................................................194

22.1 Policy Rules Overview ............................................................................................................... 194

22.1.1 What You Can Do ............................................................................................................. 194

22.2 Configuring Policy Rules ............................................................................................................ 194

22.3 Policy Example ............................................................................................................................ 197

Table of Contents

GS2220 Series User’s Guide

Chapter 23

Queuing Method..............................................................................................................................198

23.1 Queuing Method Overview ..................................................................................................... 198

23.1.1 What You Can Do ............................................................................................................. 198

23.1.2 What You Need to Know ................................................................................................. 198

23.2 Configuring Queuing ................................................................................................................. 199

Chapter 24

Multicast............................................................................................................................................201

24.1 Multicast Overview ..................................................................................................................... 201

24.1.1 What You Can Do ............................................................................................................. 201

24.1.2 What You Need to Know ................................................................................................. 201

24.2 Multicast Setup ........................................................................................................................... 205

24.3 IPv4 Multicast Status .................................................................................................................. 205

24.3.1 IGMP Snooping ................................................................................................................. 206

24.3.2 IGMP Snooping VLAN ...................................................................................................... 209

24.3.3 IGMP Filtering Profile ........................................................................................................ 210

24.4 IPv6 Multicast Status .................................................................................................................. 211

24.4.1 MLD Snooping-proxy ........................................................................................................ 212

24.4.2 MLD Snooping-proxy VLAN .............................................................................................. 212

24.4.3 MLD Snooping-proxy VLAN Port Role Setting ................................................................. 214

24.4.4 MLD Snooping-proxy Filtering .......................................................................................... 216

24.4.5 MLD Snooping-proxy Filtering Profile ............................................................................... 217

24.5 General MVR Configuration ..................................................................................................... 218

24.5.1 MVR Group Configuration .............................................................................................. 220

24.5.2 MVR Configuration Example ........................................................................................... 222

Chapter 25

AAA...................................................................................................................................................224

25.1 AAA Overview ........................................................................................................................... 224

25.1.1 What You Can Do ............................................................................................................. 224

25.1.2 What You Need to Know ................................................................................................. 225

25.2 AAA Screens ............................................................................................................................... 225

25.3 RADIUS Server Setup .................................................................................................................. 226

25.4 TACACS+ Server Setup .............................................................................................................. 227

25.5 AAA Setup .................................................................................................................................. 229

25.6 Technical Reference .................................................................................................................. 231

25.6.1 Vendor Specific Attribute ................................................................................................ 231

25.6.2 Supported RADIUS Attributes ........................................................................................... 233

25.6.3 Attributes Used for Authentication .................................................................................. 233

25.6.4 Attributes Used for Accounting ....................................................................................... 234

Table of Contents

GS2220 Series User’s Guide

Chapter 26

IP Source Guard...............................................................................................................................237

26.1 IP Source Guard Overview ........................................................................................................ 237

26.1.1 What You Can Do ............................................................................................................. 237

26.1.2 What You Need to Know ................................................................................................ 238

26.2 IP Source Guard .......................................................................................................................... 239

26.3 IPv4 Source Guard Setup .......................................................................................................... 240

26.4 IPv4 Source Guard Static Binding ............................................................................................. 240

26.5 DHCP Snooping .......................................................................................................................... 242

26.6 DHCP Snooping Configure ........................................................................................................ 245

26.6.1 DHCP Snooping Port Configure ...................................................................................... 246

26.6.2 DHCP Snooping VLAN Configure .................................................................................... 247

26.6.3 DHCP Snooping VLAN Port Configure ............................................................................ 248

26.7 ARP Inspection Status ................................................................................................................. 249

26.7.1 ARP Inspection VLAN Status ............................................................................................. 250

26.7.2 ARP Inspection Log Status ................................................................................................ 251

26.8 ARP Inspection Configure .......................................................................................................... 252

26.8.1 ARP Inspection Port Configure ........................................................................................ 253

26.8.2 ARP Inspection VLAN Configure ..................................................................................... 255

26.9 IPv6 Source Guard Overview ................................................................................................... 255

26.10 IPv6 Source Binding Status ....................................................................................................... 256

26.11 IPv6 Static Binding Setup ........................................................................................................ 257

26.12 IPv6 Source Guard Policy Setup ............................................................................................ 258

26.13 IPv6 Source Guard Port Setup ................................................................................................ 259

26.14 IPv6 Snooping Policy Setup .................................................................................................... 260

26.15 IPv6 Snooping VLAN Setup ..................................................................................................... 261

26.16 IPv6 DHCP Trust Setup ............................................................................................................. 262

26.17 Technical Reference ................................................................................................................ 263

26.17.1 DHCP Snooping Overview ............................................................................................. 263

26.17.2 ARP Inspection Overview ............................................................................................... 265

Chapter 27

Loop Guard ......................................................................................................................................267

27.1 Loop Guard Overview .............................................................................................................. 267

27.1.1 What You Can Do ............................................................................................................. 267

27.1.2 What You Need to Know ................................................................................................. 267

27.2 Loop Guard Setup ...................................................................................................................... 269

Chapter 28

VLAN Mapping.................................................................................................................................270

28.1 VLAN Mapping Overview ......................................................................................................... 270

28.1.1 VLAN Mapping Example .................................................................................................. 270

28.1.2 What You Can Do ............................................................................................................. 270

Table of Contents

GS2220 Series User’s Guide

28.2 Enable VLAN Mapping .............................................................................................................. 271

28.2.1 VLAN Mapping Configure ............................................................................................... 271

Chapter 29

Layer 2 Protocol Tunneling..............................................................................................................273

29.1 Layer 2 Protocol Tunneling Overview ......................................................................................273

29.1.1 What You Can Do ............................................................................................................. 273

29.1.2 What You Need to Know ................................................................................................. 273

29.2 Configuring Layer 2 Protocol Tunneling ................................................................................... 274

Chapter 30

PPPoE.................................................................................................................................................277

30.1 PPPoE Intermediate Agent Overview ..................................................................................... 277

30.1.1 What You Can Do ............................................................................................................. 277

30.1.2 What You Need to Know ................................................................................................. 277

30.2 PPPoE Screen .............................................................................................................................. 279

30.3 PPPoE Intermediate Agent ....................................................................................................... 280

30.3.1 PPPoE IA Per-Port .............................................................................................................. 281

30.3.2 PPPoE IA Per-Port Per-VLAN ............................................................................................ 282

30.3.3 PPPoE IA for VLAN ............................................................................................................ 283

Chapter 31

Error Disable......................................................................................................................................285

31.1 Error Disable Overview .............................................................................................................. 285

31.1.1 CPU Protection Overview ................................................................................................ 285

31.1.2 Error-Disable Recovery Overview .................................................................................... 285

31.1.3 What You Can Do ............................................................................................................. 285

31.2 Error Disable Screen .................................................................................................................... 286

31.3 Error-Disable Status .................................................................................................................... 286

31.4 CPU Protection Configuration .................................................................................................. 288

31.5 Error-Disable Detect Configuration ......................................................................................... 289

31.6 Error-Disable Recovery Configuration .....................................................................................290

Chapter 32

Private VLAN....... .... .... .................. .... .... ... ..................................... .... ... .... .........................................291

32.1 Private VLAN Overview ............................................................................................................. 291

32.2 Configuring Private VLAN .......................................................................................................... 291

Chapter 33

Green Ethernet.............. .... ................... ... .... .... .................. .... ... .... .................. .... .... .... ......................293

33.1 Green Ethernet Overview ......................................................................................................... 293

33.2 Configuring Green Ethernet ...................................................................................................... 293

Table of Contents

GS2220 Series User’s Guide

Chapter 34

Link Layer Discovery Protocol (LLDP) .............................................................................................295

34.1 LLDP Overview ............................................................................................................................ 295

34.2 LLDP-MED Overview ................................................................................................................... 296

34.3 LLDP Screens ............................................................................................................................... 297

34.4 LLDP Local Status ....................................................................................................................... 298

34.4.1 LLDP Local Port Status Detail ..........................................................................................299

34.5 LLDP Remote Status ................................................................................................................... 302

34.5.1 LLDP Remote Port Status Detail ...................................................................................... 303

34.6 LLDP Configuration .................................................................................................................... 309

34.6.1 Basic TLV Setting ............................................................................................................... 310

34.6.2 Org-specific TLV Setting .................................................................................................. 311

34.7 LLDP-MED Configuration ........................................................................................................... 312

34.8 LLDP-MED Network Policy ......................................................................................................... 313

34.9 LLDP-MED Location ................................................................................................................... 314

Chapter 35

Anti-Arpscan ....................................................................................................................................317

35.1 Anti-Arpscan Overview .............................................................................................................. 317

35.1.1 What You Can Do ............................................................................................................. 317

35.1.2 What You Need to Know ................................................................................................. 317

35.2 Anti-Arpscan Status ................................................................................................................... 318

35.3 Anti-Arpscan Host Status ........................................................................................................... 318

35.4 Anti-Arpscan Trust Host ............................................................................................................. 319

35.5 Anti-Arpscan Configure ............................................................................................................ 320

Chapter 36

BPDU Guard......................................................................................................................................322

36.1 BPDU Guard Overview .............................................................................................................. 322

36.1.1 What You Can Do ............................................................................................................. 322

36.2 BPDU Guard Status ..................................................................................................................... 322

36.3 BPDU Guard Configuration ....................................................................................................... 323

Chapter 37

OAM..................................................................................................................................................325

37.1 OAM Overview .......................................................................................................................... 325

37.1.1 What You Can Do ............................................................................................................. 325

37.2 OAM Status .................................................................................................................................. 325

37.2.1 OAM Details ....................................................................................................................... 326

37.3 OAM Configuration .................................................................................................................... 329

37.4 OAM Remote Loopback ........................................................................................................... 331

Table of Contents

GS2220 Series User’s Guide

Chapter 38

ZULD...................................................................................................................................................332

38.1 ZULD Overview ........................................................................................................................... 332

38.1.1 What You Can Do ............................................................................................................. 332

38.1.2 What You Need to Know ................................................................................................. 332

38.2 ZULD Status .................................................................................................................................. 333

38.3 ZULD Configuration ................................................................................................................... 334

Chapter 39

Static Route.......................................................................................................................................336

39.1 Static Routing Overview .......................................................................................................... 336

39.1.1 What You Can Do ............................................................................................................. 336

39.2 Static Routing .............................................................................................................................. 337

39.3 IPv4 Static Route ........................................................................................................................ 337

Chapter 40

Differentiated Services ....................................................................................................................339

40.1 DiffServ Overview ...................................................................................................................... 339

40.1.1 DSCP and Per-Hop Behavior ........................................................................................... 339

40.1.2 DiffServ Network Example ...............................................................................................339

40.2 Activating DiffServ ..................................................................................................................... 340

40.3 DSCP Settings .............................................................................................................................. 341

40.3.1 Configuring DSCP Settings ...............................................................................................341

Chapter 41

DHCP .................................................................................................................................................343

41.1 DHCP Overview .......................................................................................................................... 343

41.1.1 What You Can Do ............................................................................................................. 343

41.1.2 What You Need to Know ................................................................................................. 343

41.2 DHCP Configuration ................................................................................................................... 344

41.3 DHCPv4 Status ........................................................................................................................... 344

41.4 DHCPv4 Relay ............................................................................................................................ 344

41.4.1 DHCPv4 Relay Agent Information ................................................................................... 345

41.4.2 DHCPv4 Option 82 Profile ................................................................................................. 346

41.4.3 Configuring DHCPv4 Global Relay ................................................................................. 347

41.4.4 DHCPv4 Global Relay Port Configure ........................................................................... 348

41.4.5 Global DHCP Relay Configuration Example .................................................................. 349

41.4.6 Configuring DHCP VLAN Settings ................................................................................. 349

41.4.7 DHCPv4 VLAN Port Configure ........................................................................................ 350

41.4.8 Example: DHCP Relay for Two VLANs ............................................................................. 351

41.5 DHCPv6 Relay ............................................................................................................................. 352

Table of Contents

GS2220 Series User’s Guide

Chapter 42

ARP Setup..........................................................................................................................................354

42.1 ARP Overview ............................................................................................................................ 354

42.1.1 What You Can Do ............................................................................................................. 354

42.1.2 What You Need to Know ................................................................................................. 354

42.2 ARP Setup .................................................................................................................................... 356

42.2.1 ARP Learning .................................................................................................................... 356

Chapter 43

Maintenance....................................................................................................................................358

43.1 Overview ..................................................................................................................................... 358

43.1.1 What You Can Do ............................................................................................................. 358

43.2 The Maintenance Screen ......................................................................................................... 358

43.3 Erase Running-Configuration ................................................................................................... 360

43.4 Save Configuration .................................................................................................................... 360

43.5 Reboot System ............................................................................................................................ 361

43.5.1 Factory Default ................................................................................................................. 361

43.5.2 Custom Default ................................................................................................................ 362

43.6 Firmware Upgrade ..................................................................................................................... 362

43.7 Restore Configuration .............................................................................................................. 364

43.8 Backup Configuration .............................................................................................................. 364

43.9 Auto Configuration ................................................................................................................... 365

43.10 Tech-Support ............................................................................................................................ 366

43.10.1 Tech-Support Download ................................................................................................ 367

43.11 Certificates ................................................................................................................................ 368

43.11.1 HTTPS Certificates ............................................................................................................ 369

43.12 Technical Reference ................................................................................................................ 369

43.12.1 FTP Command Line ......................................................................................................... 369

43.12.2 Filename Conventions ................................................................................................... 370

43.12.3 FTP Command Line Procedure ..................................................................................... 370

43.12.4 GUI-based FTP Clients ..................................................................................................... 371

43.12.5 FTP Restrictions ................................................................................................................ 371

Chapter 44

Access Control.................................................................................................................................372

44.1 Access Control Overview ......................................................................................................... 372

44.1.1 What You Can Do ............................................................................................................. 372

44.2 The Access Control Main Screen .............................................................................................. 372

44.3 Configuring SNMP .................................................................................................................... 373

44.3.1 Configuring SNMP Trap Group ..................................................................................... 374

44.3.2 Enabling/Disabling Sending of SNMP Traps on a Port ................................................... 375

44.3.3 Configuring SNMP User .................................................................................................. 376

44.4 Logins .......................................................................................................................................... 378

Table of Contents

GS2220 Series User’s Guide

44.5 Service Access Control ............................................................................................................ 380

44.6 Remote Management ........................................................................................................... 380

44.7 Technical Reference .................................................................................................................. 381

44.7.1 About SNMP ...................................................................................................................... 382

44.7.2 SSH Overview ..................................................................................................................... 385

44.7.3 Introduction to HTTPS ........................................................................................................ 386

44.7.4 Google Chrome Warning Messages .............................................................................. 390

Chapter 45

Diagnostic.........................................................................................................................................392

45.1 Overview ..................................................................................................................................... 392

45.2 Diagnostic .................................................................................................................................. 392

Chapter 46

System Log........................................................................................................................................394

46.1 Overview ..................................................................................................................................... 394

46.2 System Log .................................................................................................................................. 394

Chapter 47

Syslog Setup .....................................................................................................................................395

47.1 Syslog Overview .......................................................................................................................... 395

47.1.1 What You Can Do ............................................................................................................. 395

47.2 Syslog Setup ................................................................................................................................ 395

Chapter 48

Cluster Management.......................................................................................................................398

48.1 Cluster Management Overview ..............................................................................................398

48.1.1 What You Can Do ............................................................................................................. 399

48.2 Cluster Management Status ..................................................................................................... 399

48.3 Clustering Management Configuration ................................................................................ 400

48.4 Technical Reference .................................................................................................................. 401

48.4.1 Cluster Member Switch Management .......................................................................... 402

Chapter 49

MAC Table........................................................................................................................................404

49.1 MAC Table Overview ................................................................................................................ 404

49.1.1 What You Can Do ............................................................................................................. 404

49.1.2 What You Need to Know ................................................................................................. 404

49.2 Viewing the MAC Table ............................................................................................................ 405

Chapter 50

ARP Table..........................................................................................................................................407

50.1 ARP Table Overview .................................................................................................................. 407

Table of Contents

GS2220 Series User’s Guide

50.1.1 What You Can Do ............................................................................................................. 407

50.1.2 What You Need to Know ................................................................................................. 407

50.2 Viewing the ARP Table ............................................................................................................... 407

Chapter 51

Path MTU Table.................................................................................................................................409

51.1 Path MTU Overview ................................................................................................................... 409

51.2 Viewing the Path MTU Table ..................................................................................................... 409

Chapter 52

Configure Clone............ .... .... .................. .... .... ... ..................................... .... ... .... ..............................410

52.1 Overview ..................................................................................................................................... 410

52.2 Configure Clone ........................................................................................................................ 410

Chapter 53

IPv6 Neighbor Table.........................................................................................................................413

53.1 IPv6 Neighbor Table Overview ................................................................................................. 413

53.2 Viewing the IPv6 Neighbor Table ............................................................................................. 413

Chapter 54

Port Status .........................................................................................................................................415

54.1 Overview ..................................................................................................................................... 415

54.2 Port Status ................................................................................................................................... 415

54.2.1 Port Details ...................................................................................................................... 416

54.2.2 DDMI ................................................................................................................................... 419

54.2.3 DDMI Details ...................................................................................................................... 419

54.2.4 Port Utilization ................................................................................................................. 421

Part III: Troubleshooting and Appendices..................................................422

Chapter 55

Troubleshooting................................................................................................................................423

55.1 Power, Hardware Connections, and LEDs ............................................................................... 423

55.2 Switch Access and Login ........................................................................................................... 424

55.3 Switch Configuration .................................................................................................................. 425

Appendix A Customer Support ..................................................................................................... 427

Appendix B Common Services...................................................................................................... 433

Appendix C IPv6.............................................................................................................................. 436

Appendix D Legal Information ...................................................................................................... 444

Table of Contents

GS2220 Series User’s Guide

Index .................................................................................................................................................448

PART I

User’s Guide

GS2220 Series User’s Guide

CHAPTER 1

Getting to Know Your Switch

1.1 Introduction

This chapter introduces the main features and applications of the Switch. The GS2220 Series consists of

the following models:

• GS2220-10

• GS2220-10HP

• GS2220-28

• GS2220-28HP

• GS2220-50

• GS2220-50HP

References to PoE model(s) in this User's Guide only apply to GS2220-10HP, GS2220-28HP and GS2220-

50HP.

The Switch is a layer-2 standalone Ethernet switch.

The Switch supports NebulaFlex which can set the Switch to operate in either standalone or Nebula

cloud management mode. When the Switch is in standalone mode, it can be configured and

managed by the web configurator. When the Switch is in Nebula cloud management mode, it can be

managed and provisioned by the Zyxel Nebula Control Center (NCC) (see Section 8.12 on page 107).

The following table describes the hardware features of the Switch by model.

Table 1 GS2220 Series Comparison Table

FEATURE GS2220-10 GS2220-10HP GS2220-28 GS2220-28HP GS2220-50 GS2220-50HP

GbE combo ports

(dual personality

interfaces)

22 44 4 4

1 Gbps SFP

interfaces

00 00 2 2

10/100/1000 Mbps

Ethernet ports

80 240 480

10/100/1000 Mbps

PoE ports

08 024 0 48

Fan 010212

Wall-mount Yes Yes No No No No

Rack-mount Yes Yes Yes Yes Yes Yes

Chapter 1 Getting to Know Your Switch

GS2220 Series User’s Guide

Figure 1 Switch Application

1.1.1 Management Method

With its built-in web configurator, managing and configuring the Switch is easy. In addition, the Switch

can also be managed via Telnet, any terminal emulator program using the Command Line Interface

(CLI), or third-party SNMP management.

1.1.2 Management Modes

NebulaFlex means you can set the Switch to operate in either direct standalone or cloud mode (but not

both at the same time).

Use the web configurator to configure and manage the Switch directly in standalone mode or use

Nebula Control Center (NCC) to configure and manage the Switch in cloud mode. The Nebula Control

Center (NCC) is an alternative cloud-based network management system that allows you to remotely

manage and monitor the Switch. You may also access a minimized version of the web configurator in

cloud mode.

Nebula Cloud Management

To have Nebula manage the Switch, you must first register it at the Nebula web portal at https://

nebula.zyxel.com, and ensure that Nebula Control Center Discovery is enabled in Basic Setting > Cloud

Management > Nebula Control Center Discovery in the Switch web configurator.

Chapter 1 Getting to Know Your Switch

GS2220 Series User’s Guide

Note: See the Switch’s datasheet for the feature differences between standalone and

Nebula cloud management modes. You can find the Switch’s datasheet at the Zyxel

website.

See the NCC (Nebula Control Center) User’s Guide for how to configure the Switch using Nebula.

1.1.3 Mode Changing

This section describes how to change the Switch’s management mode.

Note: If you change the Switch’s management mode from standalone mode to Nebula-

managed mode, the configuration settings of the Switch will be overwritten with what

you have configured in Nebula.

Note: If you change the Switch’s management mode from Nebula-managed mode to

standalone mode, the Switch will reset to its factory-default settings

From Standalone to Nebula Cloud Management

To manage your Switch via Nebula, connect the Switch to the Internet, and register it to a site and

organization at the Nebula web portal (https://nebula.zyxel.com).

See the following steps or the Switch Quick Start Guide for how to do device registration.

Go to the NCC to Register the Switch

1Go to the Nebula web portal in one of three ways.

Chapter 1 Getting to Know Your Switch

GS2220 Series User’s Guide

• Type https://nebula.zyxel.com in a supported web browser. See the Nebula User’s Guide for more

information about supported browsers.

• Click Nebula Mode in the Switch’s login page.

• Click the Nebula icon in the upper right corner of the Switch’s web configurator.

2Click Login in the Nebula web portal. Enter your myZyxel account information. You’ll be redirected to

another screen where you can sign up for a myZyxel account if you don’t have one.

3Create an organization and a site or select an existing site.

4Register the Switch by entering its MAC address and serial number and assign it to the site. The serial

number and MAC address can be found in the Status screen or the device back label on the Switch.

Use the Zyxel Nebula Mobile App to Register the Switch

1Download and open the Zyxel Nebula Mobile app in your mobile device. Click Sign Up to create a

myZyxel account or enter your existing account information to log in.

2You should already have created an organization and a site.

3Select a site and scan the Switch's QR code to add it to the site. You can find the QR code:

• On a label on the Switch or

• On its box or

• In the web configurator at Basic > Cloud Management > Nebula Switch Registration.

See Section 3.3 on page 41 for more information about the CLOUD LED or Section 7.2 on page 74 for

more information about the Hybrid Mode field in the Status screen to see if the Switch goes into Nebula

cloud management mode successfully.

Note: The Switch goes into Nebula-managed mode automatically after it can access the

Nebula web portal and is successfully registered there. Its login password and settings

are then overwritten with what you have configured in the Nebula web portal.

From Nebula-managed to Standalone

To return to direct management standalone mode, just remove (unregister) the Switch from the

organization/site in the Nebula web portal. The Switch will reboot and restore the factory default

settings.

1.1.4 ZON Utility

You can view, manage, and configure the Switch and its neighboring devices using its built-in web

configurator, including the Neighbor Management feature(Section 7.2.1 on page 76).

In addition, Zyxel offers a proprietary software program called Zyxel One Network (ZON) Utility, It is a tool

that assists you to set up and maintain network devices in a more simple and efficient way. You can

download the ZON Utility at www.zyxel.com and install it on a PC (Windows operation system). For more

information on ZON Utility, see Section 4.3 on page 46.

1.1.5 PoE

The Switch is a Power Sourcing Equipment (PSE) because it provides a source of power via its Ethernet

ports. Each device that receives power through an Ethernet port is a Powered Device (PD).

Chapter 1 Getting to Know Your Switch

GS2220 Series User’s Guide

The Switch can adjust the power supplied to each PD according to the PoE standard the PD supports.

PoE standards are:

• IEEE 802.3af Power over Ethernet (PoE)

• IEEE 802.3at Power over Ethernet (PoE) Plus

The following table describes the PoE features of the Switch by model.

1.2 Example Applications

This section shows a few examples of using the Switch in various network environments. Note that the

Switch in the figure is just an example Switch and not your actual Switch.

1.2.1 PoE Example Application

The following example figure shows a Switch supplying PoE (Power over Ethernet) to Powered Devices

(PDs) such as an IP camera, a wireless router, an IP telephone and a general outdoor router that are not

within reach of a power outlet.

Figure 2 PoE Example Application

Table 2 Models and PoE Features

POE FEATURES GS2220-10HP GS2220-28HP GS2220-50HP

IEEE 802.3af PoE Yes Yes Yes

IEEE 802.3at PoE Plus Yes Yes Yes

Power Management Mode Consumption

Classification

Consumption

Classification

Consumption

Classification

PoE Power Budget 180W 375W 375W

Chapter 1 Getting to Know Your Switch

GS2220 Series User’s Guide

1.2.2 Backbone Example Application

The Switch is an ideal solution for small networks where rapid growth can be expected in the near future.

The Switch can be used standalone for a group of heavy traffic users. You can connect computers and

servers directly to the Switch’s port or connect other switches to the Switch.

In this example, all computers can share high-speed applications on the server. To expand the network,

simply add more networking devices such as switches, routers, computers, print servers etc.

Figure 3 Backbone Example Application

1.2.3 Bridging/Fiber Uplink Example Application

In this example, the Switch connects different company departments (RD and Sales) to the corporate

backbone. It can alleviate bandwidth contention and eliminate server and network bottlenecks. All

users that need high bandwidth can connect to high-speed department servers via the Switch. You can

provide a super-fast uplink connection by using a Gigabit Ethernet/SFP port on the Switch.

Chapter 1 Getting to Know Your Switch

GS2220 Series User’s Guide

Figure 4 Bridging/Fiber Uplink Example Application

1.2.4 High Performance Switching Example

The Switch is ideal for connecting two networks that need high bandwidth. In the following example, use

link aggregation (trunking) to connect these two networks. The Switch can provide high bandwidth at

much lower cost while still being able to use existing network adapters and switches. Moreover, the

current LAN structure can be retained as all ports can freely communicate with each other.

This helps you switch to higher-speed LANs without the need for replacing all existing Ethernet cables

and adapter cards, restructuring your network and complex maintenance.

Figure 5 High Performance Switching

1.2.5 IEEE 802.1Q VLAN Application Example

A VLAN (Virtual Local Area Network) allows a physical network to be partitioned into multiple logical

networks. Stations on a logical network belong to one or more groups. With VLAN, a station cannot

directly talk to or hear from stations that are not in the same group(s) unless such traffic first goes through

a router.

For more information on VLANs, refer to Chapter 9 on page 110.

Chapter 1 Getting to Know Your Switch

GS2220 Series User’s Guide

1.2.5.1 Tag-based VLAN Example

Ports in the same VLAN group share the same frame broadcast domain, thus increasing network

performance by reducing broadcast traffic. VLAN groups can be modified at any time by adding,

moving or changing ports without any re-cabling.

Shared resources such as a server can be used by all ports in the same VLAN as the server. In the

following figure only ports that need access to the server need to be part of VLAN 1. Ports can belong to

other VLAN groups too.

Figure 6 Shared Server Using VLAN Example

1.2.6 IPv6 Support

IPv6 (Internet Protocol version 6), is designed to enhance IP address size and features. The increase in

IPv6 address size to 128 bits (from the 32-bit IPv4 address) allows up to 3.4 x 1038 IP addresses. At the time

of writing, the Switch supports the following features.

• Static address assignment and stateless auto-configuration

• Neighbor Discovery Protocol (a protocol used to discover other IPv6 devices in a network)

• Remote Management using ping SNMP, SSH, telnet, HTTP and FTP services

• ICMPv6 to report errors encountered in packet processing and perform diagnostic functions, such as

"ping”

• IPv4/IPv6 dual stack; the Switch can run IPv4 and IPv6 at the same time

• DHCPv6 client and relay

• Multicast Listener Discovery (MLD) snooping and proxy

For more information on IPv6, refer to Appendix C on page 436 and the CLI Reference Guide.

1.3 Ways to Manage the Switch

Use any of the following methods to manage the Switch.

• Web Configurator. This is recommended for everyday management of the Switch using a (supported)

web browser. See Chapter 4 on page 43.

Chapter 1 Getting to Know Your Switch

GS2220 Series User’s Guide

• Command Line Interface. Line commands offer an alternative to the Web Configurator and may be

necessary to configure advanced features. See the CLI Reference Guide.

• FTP. Use File Transfer Protocol for firmware upgrades and configuration backup/restore. See Section

43.12.1 on page 369.

• SNMP. The device can be monitored and/or managed by an SNMP manager. See Section 44.7 on

page 381.

• Cluster Management. Cluster Management allows you to manage multiple switches through one

switch, called the cluster manager. See Chapter 48 on page 398.

• ZON Utility. ZON Utility is a program designed to help you deploy and perform initial setup on a

network more efficiently. See Section 4.3 on page 46.

• NCC (Zyxel Nebula Control Center). With the NCC, you can remotely manage and monitor the

Switch through a cloud-based network management system. See Section 8.12 on page 107 or the

NCC User’s Guide for detailed information about how to access the NCC and manage your Switch

via the NCC. See the NCC User’s Guide for how to configure Nebula managed devices.

1.4 Good Habits for Managing the Switch

Do the following things regularly to make the Switch more secure and to manage the Switch more

effectively.

• Change the password. Use a password that’s not easy to guess and that consists of different types of

characters, such as numbers and letters.

• Write down the password and put it in a safe place.

• Back up the configuration (and make sure you know how to restore it). Restoring an earlier working

configuration may be useful if the device becomes unstable or even crashes. If you forget your

password, you will have to reset the Switch to its factory default settings. If you backed up an earlier

configuration file, you would not have to totally re-configure the Switch. You could simply restore your

last configuration.

GS2220 Series User’s Guide

CHAPTER 2

Hardware Installation and

Connection

2.1 Installation Scenarios

This chapter shows you how to install and connect the Switch.

The Switch can be:

• Placed on a desktop.

• Wall-mounted on a wall.

• Rack-mounted on a standard EIA rack.

Note: Ask an authorized technician to attach the Switch to the rack/wall. See the Installation

Requirements sections in this chapter to know the types of screws and screw drivers for

each mounting method.

WARNING! Failure to use the proper screws may damage the unit.

WARNING! This Switch is not suitable for use in locations where children

are likely to be present.

See Table 1 on page 21 for the comparison table of the hardware installation methods for each model.

2.2 Desktop Installation Procedure

1Make sure the Switch is clean and dry.

2Set the Switch on a smooth, level surface strong enough to support the weight of the Switch and the

connected cables. Make sure there is a power outlet nearby.

3Make sure there is at least 40 mm of clearance from the bottom to the Switch, and make sure there is

enough clearance around the Switch to allow air circulation and the attachment of cables and the

power cord. This is especially important for enclosed rack installations.

4Remove the adhesive backing from the rubber feet.

5Attach the rubber feet to each corner on the bottom of the Switch. These rubber feet help protect the

Switch from shock or vibration and ensure space between devices when stacking.

Chapter 2 Hardware Installation and Connection

GS2220 Series User’s Guide

Figure 7 Attaching Rubber Feet

Note: Do NOT block the ventilation holes.

Note: Do NOT store things on the Switch, and allow clearance next to the ventilation holes to

prevent your Switch from overheating. This is especially crucial when your Switch

doesn’t have fan modules.

Do NOT block the ventilation holes nor store things on the Switch. Allow

clearance for the ventilation holes to prevent your Switch from

overheating. Overheating could affect the performance of your Switch,

or even damage it.

2.3 Mounting the Switch on a Rack

The Switch can be mounted on an EIA standard size, 19-inch rack or in a wiring closet with other

equipment. Follow the steps below to mount your Switch on a standard EIA rack using a rack-mounting

kit.

Note: Make sure there is enough clearance between each equipment on the rack for air

circulation.

2.3.1 Installation Requirements

• Two mounting brackets.

• Eight M3 flat head screws and a #2 Philips screwdriver.

• Four M5 flat head screws and a #2 Philips screwdriver.

Failure to use the proper screws may damage the unit.

2.3.1.1 Precautions

• Make sure the rack will safely support the combined weight of all the equipment it contains. The

maximum weight a bracket can hold is 21.5 Kg.

• Make sure the position of the Switch does not make the rack unstable or top-heavy. Take all

necessary precautions to anchor the rack securely before installing the unit.

Chapter 2 Hardware Installation and Connection

GS2220 Series User’s Guide

2.3.2 Attaching the Mounting Brackets to the Switch

1Position a mounting bracket on one side of the Switch, lining up the four screw holes on the bracket with

the screw holes on the side of the Switch.

Figure 8 Attaching the Mounting Brackets

2Using a #2 Philips screwdriver, install the M3 flat head screws through the mounting bracket holes into

the Switch.

3Repeat steps 1 and 2 to install the second mounting bracket on the other side of the Switch.

4You may now mount the Switch on a rack. Proceed to the next section.

2.3.3 Mounting the Switch on a Rack

1Position a mounting bracket (that is already attached to the Switch) on one side of the rack, lining up

the two screw holes on the bracket with the screw holes on the side of the rack.

Figure 9 Mounting the Switch on a Rack

2Using a #2 Philips screwdriver, install the M5 flat head screws through the mounting bracket holes into

the rack.

Note: Make sure you tighten all the four screws to prevent the Switch from getting slanted.

Chapter 2 Hardware Installation and Connection

GS2220 Series User’s Guide

3Repeat steps 1 and 2 to attach the second mounting bracket on the other side of the rack.

2.4 Wall Mounting (GS2220-10 and GS2220-10HP Only)

The GS2220-10 and GS2220-10HP can be mounted on a wall. You may need screw anchors if mounting

on a concrete or brick wall.

2.4.1 Installation Requirement

• Distance between holes: 78mm

• Two M4 screws and a #2 Philips screwdriver

• Two screw anchors (optional)

1Select a position free of obstructions on a wall strong enough to hold the weight of the Switch.

2Mark two holes on the wall at the appropriate distance apart for the screws.

WARNING! Be careful to avoid damaging pipes or cables located inside

the wall when drilling holes for the screws.

3If using screw anchors, drill two holes for the screw anchors into the wall. Push the anchors into the full

depth of the holes, then insert the screws into the anchors. Do not insert the screws all the way in - leave

a small gap of about 0.5 cm.

If not using screw anchors, use a screwdriver to insert the screws into the wall. Do not insert the screws all

the way in - leave a gap of about 0.5 cm.

4Make sure the screws are fastened well enough to hold the weight of the Switch with the connection

cables.

5Align the holes on the back of the Switch with the screws on the wall. Hang the Switch on the screws.

Chapter 2 Hardware Installation and Connection

GS2220 Series User’s Guide

Note: Make sure there is enough clearance between the wall and the Switch to allow

ventilation.

WARNING! The Switch should be wall-mounted horizontally, and make

sure the front panel is facing down. The Switch's side panels with

ventilation slots should not be facing up or down as this position is less

safe.

GS2220 Series User’s Guide

CHAPTER 3

Hardware Overview

This chapter describes the front panel and rear panel of the Switch and shows you how to make the

hardware connections.

3.1 Front Panel Connections

The figure below shows the front panel of the Switch.

Figure 10 Front Panel: GS2220-10

Figure 11 Front Panel: GS2220-10HP

Figure 12 Front Panel: GS2220-28

Figure 13 Front Panel: GS2220-28HP

Figure 14 Front Panel: GS2220-50

Figure 15 Front Panel: GS2220-50HP

Chapter 3 Hardware Overview

GS2220 Series User’s Guide

The following table describes the ports.

3.1.1 SFP Slots

These are slots for SFP (Small Form-Factor Pluggable) transceivers. A transceiver is a single unit that

houses a transmitter and a receiver. The Switch does not come with transceivers. You must use

transceivers that comply with the Small Form-factor Pluggable (SFP) Transceiver MultiSource Agreement

(MSA). See the SFF committee’s INF-8074i specification Rev 1.0 for details.

You can change transceivers while the Switch is operating. You can use different transceivers to

connect to Ethernet switches with different types of fiber-optic or even copper cable connectors.

• Type: SFP connection interface

• Connection speed: 100/1000 Mbps per second

To avoid possible eye injury, do not look into an operating fiber-optic

module’s connectors.

3.1.1.1 Transceiver Installation

Use the following steps to install a transceiver.

Table 3 Panel Connections

CONNECTOR DESCRIPTION

2 SFP Slots Use SFP transceivers in these ports for high-bandwidth backbone connections.

8/24/48 1000Base-T

RJ-45 Ethernet Ports

These are 1000Base-T auto-negotiating and auto-crossover Ethernet ports.

Connect these ports to a computer, a hub, a router, or an Ethernet switch.

2/4 GbE Combo

Ports (Dual

Personality

Interfaces)

Each interface has one 1000Base-T copper RJ-45 port and one SFP slot, with one port active

at a time.

• 1000Base-T Ports:

Connect these ports to a computer, an Ethernet switch or router.

•SFP Slots:

Use Small Form-Factor Pluggable (SFP) transceivers in these ports for fiber-optic

connections to an Ethernet switch or router.

Reset Press the RESET button to reboot the Switch without turning the power off. See Section 3.3 on

page 40 for more information about the LED behavior.

Restore Press the RESTORE button for three to six seconds to have the Switch automatically reboot

and restore the last-saved custom default file. See Section 3.3 on page 41 for more

information about the LED behavior.

Press the RESTORE button for more than seven seconds to have the Switch automatically

reboot and restore the factory default file. See Section 3.3 on page 41 for more information

about the LED behavior.

PoE Mode

(only available for

GS2220-50HP)

Push or release this button to change how the Link/ACT LED works.

• Each Ethernet port’s LED is changed to act as a PoE Mode LED by pushing the PoE MODE

button on the front panel.

• Each Ethernet port’s LED is changed back to act as a Link/ACT LED by releasing the PoE

MODE button on the front panel.

View the LEDs to ensure proper functioning of the Switch and as an aid in troubleshooting

(see Section 3.3 on page 41).

Console Port Only connect this port to your computer (using an RS-232 cable) if you want to configure the

Switch using the command line interface (CLI) via the console port.

Chapter 3 Hardware Overview

GS2220 Series User’s Guide

1Insert the transceiver into the slot with the exposed section of PCB board facing down.

Figure 16 Transceiver Installation Example

2Press the transceiver firmly until it clicks into place.

3The Switch automatically detects the installed transceiver. Check the LEDs to verify that it is functioning

properly.

Figure 17 Installed Transceiver

3.1.1.2 Transceiver Removal

Use the following steps to remove a transceiver.

1Open the transceiver’s latch (latch styles vary).

Figure 18 Opening the Transceiver’s Latch Example

2Pull the transceiver out of the slot.

Figure 19 Transceiver Removal Example

Chapter 3 Hardware Overview

GS2220 Series User’s Guide

3.1.2 Ethernet Ports

The Switch has 1000Base-T auto-negotiating, auto-crossover Ethernet ports. In 10/100/1000 Mbps

Gigabit, the speed can be 10 Mbps, 100 Mbps or 1000 Mbps and the duplex mode can be half duplex

or full duplex.

An auto-negotiating port can detect and adjust to the optimum Ethernet speed (10/100 Mbps and 1

Gbps) and full duplex mode of the connected device.

An auto-crossover (auto-MDI/MDI-X) port automatically works with a straight-through or crossover

Ethernet cable.

When auto-negotiation is turned on, an Ethernet port negotiates with the peer automatically to

determine the connection speed and duplex mode. If the peer Ethernet port does not support auto-

negotiation or turns off this feature, the Switch determines the connection speed by detecting the signal

on the cable. When the Switch’s auto-negotiation is turned off, an Ethernet port uses the pre-configured

speed and duplex mode when making a connection, thus requiring you to make sure that the settings

of the peer Ethernet port are the same in order to connect.

3.1.2.1 Default Ethernet Negotiation Settings

The factory default negotiation settings for the Ethernet ports on the Switch are:

• Speed: Auto

•Duplex: Auto

• Flow control: Off

• Dual Personality Interface: Fiber-optic module first

3.1.2.2 Auto-Crossover

All ports support auto-crossover, that is auto-MDIX ports (Media Dependent Interface Crossover), so you

may use either a straight-through Ethernet cable or crossover Ethernet cable for all Gigabit port

connections. Auto-crossover ports automatically sense whether they need to function as crossover or

straight ports, so crossover cables can connect both computers and switches/hubs.

3.1.3 PoE (GS2220-10HP, GS2220-28HP and GS2220-50HP)

The Switch supports the IEEE 802.3af Power over Ethernet (PoE) and IEEE 802.3at Power over Ethernet

(PoE) plus. The Switch is a Power Sourcing Equipment (PSE) because it provides a source of power via its

Ethernet ports. Each device that receives power through an Ethernet port is a Powered Device (PD).

3.1.4 Dual Personality Interfaces

A combo port is for uplink connections. It consists of a Gigabit Ethernet port for Ethernet connection,

and a SFP transceiver slot for fiber connection. The fiber connection takes priority if the corresponding

Gigabit port is also connected.

• 100 Mbps/1 Gbps - Connect these ports to high-bandwidth backbone network Ethernet switches.

• Transceiver Slots - Use SFP transceivers in these slots for connections to backbone Ethernet switches.

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Figure 20 Combo Port Example: Gigabit Port and SFP Transceiver Slot

3.1.5 Console Port

For local management, you can use a computer with terminal emulation software configured to the

following parameters:

• VT100 terminal emulation

• 115200 bps

• No parity, 8 data bits, 1 stop bit

• No flow control

Connect the male 9-pin end of the RS-232 console cable to the console port of the Switch. Connect the

female end to a serial port (COM1, COM2 or other COM port) of your computer.

3.2 Rear Panel

The following figures show the rear panels of the Switch. The rear panels contain:

Figure 21 Rear Panel: GS2220-10

Figure 22 Rear Panel: GS2220-10HP

Figure 23 Rear Panel: GS2220-28

Figure 24 Rear Panel: GS2220-28HP

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Figure 25 Rear Panel: GS2220-50

Figure 26 Rear Panel: GS2220-50HP

3.2.1 Grounding

Grounding is a safety measure to have unused electricity return to the ground. It prevents damage to

the Switch, and protects you from electrocution.

Note: The Switch must be grounded by qualified service personnel.

1Remove the M4 ground screw from the Switch’s rear panel.

2Secure a green/yellow ground cable (16 AWG or smaller) to the Switch's rear panel using the M4 ground

screw.

3Attach the other end of the cable to the ground, either to the same ground electrode as the rack you

installed the device on or to the main grounding electrode of the building.

Follow your country's regulations and safety instructions to electrically ground the device properly.

Warning! Connect the ground cable before you connect any other

cables or wiring.

Figure 27 Grounding

3.2.2 AC Power Connection

Make sure you are using the correct power source and that no objects obstruct the airflow of the fans.

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The Switch uses two power supply modules, one of which is redundant, so if one power module fails the

system can operate on the remaining module.

Connecting the Power

Use the following procedures to connect the Switch to a power source after you have installed it in a

rack.

Note: Use the included power cord for the AC power connection.

1Connect the female end of the power cord to the AC power socket.

2Connect the other end of the cord to a power outlet.

Disconnecting the Power

The power input connectors can be disconnected from the power source individually.

1Disconnect the power cord from the power outlet.

2Disconnect the power cord from the AC power socket.

3.3 LEDs

The following table describes the LEDs.

Table 4 LEDs

LED COLOR STATUS DESCRIPTION

PWR Green On The Switch is receiving power from the power source.

Blinking The Switch is returning to the last-saved custom default configuration settings.

Amber On The Switch is returning to its factory default configuration settings.

Off The Switch is not receiving power from the power source.

SYS (System) Green On The Switch is on and functioning properly.

Blinking The Switch is rebooting and performing self-diagnostic tests.

Red On The Switch is functioning abnormally.

Off The power is off or the system is not ready/malfunctioning.

CLOUD Green On The Switch has successfully connected to the NCC (Nebula Control Center).

Blinking The Switch cannot connect to the NCC because it is not registered.

Amber On The Switch is registered at the NCC but cannot connect to the NCC. Please

check the Internet connection of the Switch.

Blinking The Switch is not registered at the NCC and cannot connect to the NCC. Please

check the Internet connection of the Switch and register the Switch at NCC.

Off The Switch is operating in standalone mode. Nebula Control Center Discovery is

disabled in Basic > Cloud Management > Nebula Control Center Discovery in the

Switch Web Configurator.

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LOCATOR Blue On The Switch is uploading firmware. While the Switch is doing this, don’t turn off the

power.

Blinking Shows the actual location of the Switch between several devices in a rack. The

default timer is 30 minutes when you are configuring the Switch.

Off The locator is not functioning or malfunctioning.

PoE Usage MAX

(GS2220-10HP)

Bar1 is the bar at

the bottom; bar 5

is the bar at the

top.

Green

(Bar1-

Bar3)

On Each bar represents 20% of PoE Power consumption.

Bar 1: PoE power usage is below 20 percent of the power supplied budget.

Bar 2: PoE power usage is below 40 percent of the power supplied budget, but

over 20 percent of the power supplied budget.

Bar 3: PoE power usage is below 60 percent of the power supplied budget, but

over 40 percent of the power supplied budget.

Yellow

(Bar4)

On PoE power usage is below 80 percent of the power supplied budget, but over 60

percent of the power supplied budget.

Red

(Bar5)

On PoE power usage is more than 80 percent of the power supplied budget.

Blinking Less than 5 percent of the power supplied budget remains. 5 percent is the

default value.

Off PoE power usage is 0 percent of the power supplied budget.

PoE MAX

(GS2220-28HP

and GS2220-

50HP)

Amber On Less than 5 percent of the power supplied budget remains. 5 percent is the

default value.

Off The Switch has a sufficient power supplied budget.

RJ-45 Ethernet Port

LINK/ACT Green On The link to a 1000 Mbps Ethernet network is up.

Blinking The Switch is transmitting/receiving to/from a 1000 Mbps Ethernet network.

Amber On The link to a 100/10 Mbps Ethernet network is up.

Blinking The Switch is transmitting/receiving to/from a 100/10 Mbps Ethernet network.

Off The link to an Ethernet network is down.

PoE Mode

(GS2220-10HP,

GS2220-28HP

and GS2220-

50HP)

Green On Power supplied to all PoE Ethernet ports meets the IEEE 802.3at standard.

Amber On Power supplied to all PoE Ethernet ports meets the IEEE 802.3af standard.

Off There is no power supplied.

SFP Slots

LINK/ACT Green On The port has a successful 1000 Mbps connection.

Blinking The port is transmitting or receiving data at 1000 Mbps.

Amber On The port has a successful 100 Mbps connection.

Blinking The port is transmitting or receiving data at 100 Mbps.

Off This link is disconnected.

Table 4 LEDs (continued)

LED COLOR STATUS DESCRIPTION

GS2220 Series User’s Guide

CHAPTER 4

The Web Configurator

4.1 Overview

This section introduces the configuration and functions of the web configurator.

The web configurator is an HTML-based management interface that allows easy Switch setup and

management via Internet browser. Use Internet Explorer 9.0 and later versions, Mozilla Firefox 21 and

later versions, Safari 6.0 and later versions or Google Chrome 26.0 and later versions. The recommended

screen resolution is 1024 by 768 pixels.

In order to use the web configurator you need to allow:

• Web browser pop-up windows from your device. Web pop-up blocking is enabled by default in

Windows XP SP (Service Pack) 2.

• JavaScript (enabled by default).

• Java permissions (enabled by default).

4.2 System Login

1Start your web browser.

2The Switch is a DHCP client by default. Type “http://DHCP-assigned IP” in the Location or Address field.

Press [ENTER].

If the Switch is not connected to a DHCP server, type “http://” and the static IP address of the Switch (for

example, the default management IP address is 192.168.1.1) in the Location or Address field. Press

[ENTER]. Your computer must be in the same subnet in order to access this website address.

Also, you can use the ZON Utility to check your Switch’s IP address. See Section 4.3 on page 46 for more

information on the ZON utility.

3The following screen appears.

You can click the play icon to watch a tutorial video on how to create an NCC account or click the link

to access the NCC portal. The NCC is a cloud- based network management system that allows you to

remotely manage and monitor the Switch in Nebula cloud management mode. Click Standalone Mode

to go back to the login screen and continue with the next step.

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Figure 28 Web Configurator > Login: Nebula Mode

4Click Login to log into the web configurator to manage the Switch directly. The default username is

admin and associated default password is 1234.

Figure 29 Web Configurator > Login

5After you log into the web configurator, you will see the following screen encouraging you to use NCC.

The screen has a QR code containing the Switch’s serial number and MAC address for NCC registration

of the Switch using the Nebula Mobile app. First, download the app from the Google Play store for

Android devices or the App Store for iOS devices and create an organization and site at NCC.

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Figure 30 Web Configurator: Message

You may also access this screen at Basic Setting > Cloud Management > Nebula Switch Registration.

6If you didn’t change the default administrator password and/or SNMP community values, a warning

screen displays each time you log into the web configurator. Click Password / SNMP to open a screen

where you can change the administrator and SNMP passwords simultaneously. Otherwise, click Ignore

to close it.

Figure 31 Web Configurator: Warning

Figure 32 Web Configurator: Password

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Change the default administrator and/or SNMP passwords, and then click Apply to save your changes.

4.3 Zyxel One Network (ZON) Utility

ZON Utility is a program designed to help you deploy and manage a network more efficiently. It detects

devices automatically and allows you to do basic settings on devices in the network without having to

be near it.

The ZON Utility issues requests via Zyxel Discovery Protocol (ZDP) and in response to the query, the device

responds back with basic information including IP address, firmware version, location, system and model

name in the same broadcast domain. The information is then displayed in the ZON Utility screen and you

can perform tasks like basic configuration of the devices and batch firmware upgrade in it. You can

download the ZON Utility at www.zyxel.com and install it on a PC (Windows operating system).

4.3.1 Requirements

Before installing the ZON Utility on your PC, please make sure it meets the requirements listed below.

Table 5 Web Configurator: Password/SNMP

LABEL DESCRIPTION

Administrator

This is the default administrator account with the “admin” user name. You cannot change the default administrator

user name.

Old Password Type the existing system password (1234 is the default password when shipped).

New Password Enter your new system password.

Retype to Confirm Retype your new system password for confirmation.

General Setting

Use this section to specify the SNMP version and community (password) values.

Version Select the SNMP version for the Switch. The SNMP version on the Switch must match the

version on the SNMP manager. Choose SNMP version 2c (v2c), SNMP version 3 (v3) or both

(v3v2c).

Note: SNMP version 2c is backwards compatible with SNMP version 1.

Get Community Enter the Get Community string, which is the password for the Incoming Get- and GetNext-

requests from the management station.

The Get Community string is only used b SNMP managers using SNMP version 2c or lower.

Set Community Enter the Set Community string, which is the password for the incoming Set- requests from the

management station.

The Set Community string is only used by SNMP managers using SNMP version 2c or lower.

Trap Community Enter the Trap Community string, which is the password sent with each trap to the SNMP

managers.

The Trap Community string is only used by SNMP managers using SNMP version 2c or lower,.

Apply Click Apply to save your changes to the Switch’s run-time memory, The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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Operating System

At the time of writing, the ZON Utility is compatible with:

• Windows 7 (both 32-bit / 64-bit versions)

• Windows 8 (both 32-bit / 64-bit versions)

• Windows 8.1 (both 32-bit / 64-bit versions)

• Window 10 (both 32-bit / 64-bit versions)

Note: To check for your Windows operating system version, right-click on My Computer >

Properties. You should see this information in the General tab.

Note: It is suggested that you install Npcap, the packet capture library for Windows operating

systems, and remove WinPcap or any other installed packet capture tools before you

install the ZON utility.

Hardware

Here are the minimum hardware requirements to use the ZON Utility on your PC.

• Core i3 processor

•2GB RAM

• 100MB free hard disk

• WXGA (Wide XGA 1280x800)

4.3.2 Run the ZON Utility

1Double-click the ZON Utility to run it.

2The first time you run the ZON Utility, you will see if your device and firmware version support the ZON

Utility. Click the OK button to close this screen.

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Figure 33 Supported Devices and Versions

If you want to check the supported models and firmware versions later, you can click the Show

information about ZON icon in the upper right hand corner of the screen. Then select the Supported

model and firmware version link. If your device is not listed here, see the device release notes for ZON

utility support. The release notes are in the firmware zip file on the Zyxel web site.

Figure 34 ZON Utility Screen

3Select a network adapter to which your supported devices are connected.

4Click the Go button for the ZON Utility to discover all supported devices in your network.

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Figure 35 Discovery

5The ZON Utility screen shows the devices discovered.

Figure 36 ZON Utility Screen

6Select a device and then use the icons to perform actions. Some functions may not be available for

your devices.

Note: You must know the selected device admin password before taking actions on the

device using the ZON utility icons.

Figure 37 Password Prompt

The following table describes the icons numbered from left to right in the ZON Utility screen.

12345678910 11 12 13

Table 6 ZON Utility Icons

ICON DESCRIPTION

1 IP configuration Change the selected device’s IP address.

2 Renew IP Address Update a DHCP-assigned dynamic IP address.

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The following table describes the fields in the ZON Utility main screen.

3 Reboot Device Use this icon to restart the selected device(s). This may be useful when troubleshooting

or upgrading new firmware.

4 Reset Configuration to

Default

If you forget your password or cannot access the Web Configurator, you can use this

icon to reload the factory-default configuration file. This means that you will lose all

configurations that you had previously.

5 Locator LED Use this icon to locate the selected device by causing its Locator LED to blink.

6 Web GUI Use this to access the selected device web configurator from your browser. You will

need a username and password to log in.

7 Firmware Upgrade Use this icon to upgrade new firmware to selected device(s) of the same model.

Online upgrade: If there’s the latest firmware available, it’ll show in the drop-down

menu. You don’t need to download the firmware first to upgrade firmware.

Local upgrade: Make sure you have downloaded the firmware from the Zyxel website

to your computer and unzipped it in advance.

8 Change Password Use this icon to change the admin password of the selected device. You must know

the current admin password before changing to a new one.

9 Configure NCC

Discovery

You must have Internet access to use this feature. Use this icon to enable or disable the

Nebula Control Center (NCC) discovery feature on the selected device. If it’s

enabled, the selected device will try to connect to the NCC. Once the selected

device is connected to and has registered in the NCC, it’ll go into the Nebula cloud

management mode.

10 ZAC Use this icon to run the Zyxel AP Configurator of the selected AP.

11 Clear and Rescan Use this icon to clear the list and discover all devices on the connected network again.

12 Save Configuration Use this icon to save configuration changes to permanent memory on a selected

device.

13 Settings Use this icon to select a network adaptor for the computer on which the ZON utility is

installed, and the utility language.

Table 7 ZON Utility Fields

LABEL DESCRIPTION

Type This field displays an icon of the kind of device discovered.

Model This field displays the model name of the discovered device.

Firmware Version This field displays the firmware version of the discovered device.

MAC Address This field displays the MAC address of the discovered device.

IP Address This field displays the IP address of an internal interface on the discovered device that first

received an ZDP discovery request from the ZON utility.

System Name This field displays the system name of the discovered device.

Location This field displays where the discovered device is.

Status This field displays whether changes to the discovered device have been done

successfully. As the Switch does not support IP Configuration, Renew IP address and

Locator LED, this field displays “Update failed”, “Not support Renew IP address” and “Not

support Flash Locator LED” respectively.

NCC Discovery This field displays if the discovered device supports the Nebula Control Center (NCC)

discovery feature. If it’s enabled, the selected device will try to connect to the NCC. Once

the selected device is connected to and has registered in the NCC, it’ll go into the Nebula

cloud management mode.

Table 6 ZON Utility Icons

ICON DESCRIPTION

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4.4 The Web Configurator Layout

The Status screen is the first screen that displays when you access the web configurator.

The following figure shows the navigating components of a web configurator screen.

Figure 38 The Web Configurator Layout

A - Click the menu items to open submenu links, and then click on a submenu link to open the screen in

the main window.

B, C, D, E, F, G- These are quick links which allow you to perform certain tasks no matter which screen you

are currently working in.

B - Click this link to update the information in the screen you are viewing currently.

C - Click this link to save your configuration into the Switch’s nonvolatile memory. Nonvolatile memory is

saved in the configuration file from which the Switch booted from and it stays the same even if the

Switch’s power is turned off. See Section 43.4 on page 360 for information on saving your settings to a

specific configuration file.

Serial Number Enter the admin password of the discovered device to display its serial number.

Hardware Version This field displays the hardware version of the discovered device.

Table 7 ZON Utility Fields

LABEL DESCRIPTION

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D - Click this link to go to the status page of the Switch.

E - Click this link to log out of the web configurator.

F - Click this link to display web help pages. The help pages provide descriptions for all of the

configuration screens.

G - Click this link to go to the NCC (Nebula Control Center) portal website.

H - Click this link to go to the Neighbor screen where you can see and manage neighbor devices

learned by the Switch.

In the navigation panel, click a main link to reveal a list of submenu links.

Table 8 Navigation Panel Sub-links Overview

BASIC SETTING ADVANCED

APPLICATION IP APPLICATION MANAGEMENT

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The following table describes the links in the navigation panel.

Table 9 Navigation Panel Links

LINK DESCRIPTION

Basic Settings

System Info This link takes you to a screen that displays general system and hardware monitoring

information.

General Setup This link takes you to a screen where you can configure general identification information and

time settings for the Switch.

Switch Setup This link takes you to a screen where you can set up global Switch parameters such as VLAN

type, MAC address learning, GARP and priority queues.

IP Setup This link takes you to a screen where you can configure the IP address, subnet mask

(necessary for Switch management) and set up to 64 IP routing domains.

Port Setup This link takes you to screens where you can configure speed, flow control and priority settings

for individual Switch ports.

PoE Setup For PoE model(s).

This link takes you to a screen where you can set priorities, PoE power-up settings and

schedule so that the Switch is able to reserve and allocate power to certain PDs.

Interface Setup This link takes you to a screen where you can create virtual interfaces on the Switch.

IPv6 This link takes you to a screen where you can enable an IPv6 interface and configure the IPv6

settings on the Switch.

DNS This link takes you to a screen where you can configure DNS (domain name server) IP

addresses.

Cloud

Management

This screen displays a link to a screen where you can enable or disable the Nebula Control

Center Discovery feature. If it’s enabled, you can have the Switch search for the NCC

(Nebula Control Center). Another link takes you to the Nebula Switch Registration screen

which has a QR code containing the Switch’s serial number and MAC address for handy

registration of the Switch at NCC.

Advanced Application

VLAN This link takes you to screens where you can configure port-based or 802.1Q VLAN

(depending on what you configured in the Switch Setup menu). You can also configure a

protocol based VLAN or a subnet based VLAN in these screens.

Static MAC

Forwarding

This link takes you to screens where you can configure static MAC addresses for a port. These

static MAC addresses do not age out.

Static Multicast

Forwarding

This link takes you to a screen where you can configure static multicast MAC addresses for

port(s). These static multicast MAC addresses do not age out.

Filtering This link takes you to a screen to set up filtering rules.

Spanning Tree

Protocol

This link takes you to screens where you can configure the RSTP/MRSTP/MSTP to prevent

network loops.

Bandwidth Control This link takes you to screens where you can cap the maximum bandwidth allowed on a port.

Broadcast Storm

Control

This link takes you to a screen to set up broadcast filters.

Mirroring This link takes you to screens where you can copy traffic from one port or ports to another port

in order that you can examine the traffic from the first port without interference.

Link Aggregation This link takes you to screen where you can logically aggregate physical links to form one

logical, higher-bandwidth link.

Port Authentication This link takes you to a screen where you can configure IEEE 802.1x port authentication as well

as MAC authentication for clients communicating via the Switch.

Port Security This link takes you to a screen where you can activate MAC address learning and set the

maximum number of MAC addresses to learn on a port.

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Time Range This link takes you to a screen where you can configure time range for time-oriented features

like Classifier.

Classifier This link takes you to screens where you can configure the Switch to group packets based on

the specified criteria.

Policy Rule This link takes you to a screen where you can configure the Switch to perform special

treatment on the grouped packets.

Queuing Method This link takes you to a screen where you can configure queuing with associated queue

weights for each port.

Multicast This link takes you to screen where you can configure various multicast features, IGMP

snooping, MLD snooping-proxy and create multicast VLANs.

AAA This link takes you to a screen where you can configure authentication, authorization and

accounting services via external servers. The external servers can be either RADIUS (Remote

Authentication Dial-In User Service) or TACACS+ (Terminal Access Controller Access-Control

System Plus).

IP Source Guard This link takes you to screens where you can configure filtering of unauthorized DHCP and ARP

packets in your network.

Loop Guard This link takes you to a screen where you can configure protection against network loops that

occur on the edge of your network.

VLAN Mapping This link takes you to screens where you can configure VLAN mapping settings on the Switch.

Layer 2 Protocol

Tunneling

This link takes you to a screen where you can configure L2PT (Layer 2 Protocol Tunneling)

settings on the Switch.

PPPoE This link takes you to screens where you can configure how the Switch gives a PPPoE

termination server additional subscriber information that the server can use to identify and

authenticate a PPPoE client.

Errdisable This link takes you to a screens where you can view errdisable status and configure errdisable

settings in CPU protection, errdisable detect, and errdisable recovery.

Private VLAN This link takes you to a screen where you can block traffic between ports in a VLAN on the

Switch.

Green Ethernet This link takes you to a screen where you can configure the Switch to reduce port power

consumption.

LLDP This link takes you to a screen where you can configure LLDP settings.

Anti-Arpscan This link takes you to screens where you can enable anti-arpscan on the Switch and ports,

and view the port state. You can also create trusted hosts, view blocked hosts and unblock

them.

BPDU Guard This link takes you to screens where you can enable BPDU guard on the Switch and ports, and

view the port state.

OAM This link takes you to screens where you can enable Ethernet OAM on the Switch, view the

configuration of ports on which Ethernet OAM is enabled and perform remote-loopback

tests.

ZULD This link takes you to screens where you can enable ZULD on a port and configure related

settings.

IP Application

Static Routing This link takes you to a screen where you can configure static routes. A static route defines

how the Switch should forward traffic by configuring the TCP/IP parameters manually.

DiffServ This link takes you to screens where you can enable DiffServ, configure marking rules and set

DSCP-to-IEEE802.1p mappings.

DHCP This link takes you to screens where you can configure the DHCP settings.

ARP Setup This link takes you to a screen where you can configure ARP learning mode on a per-port

basis and create static ARP entries which do not age out.

Table 9 Navigation Panel Links (continued)

LINK DESCRIPTION

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GS2220 Series User’s Guide

4.4.1 Change Your Password

After you log in for the first time, it is recommended you change the default administrator password.

Click Management > Access Control > Logins to display the next screen.

Figure 39 Change Administrator Login Password

Management

Maintenance This link takes you to screens where you can perform firmware and configuration file

maintenance as well as reboot the system.

Access Control This link takes you to screens where you can change the system login password and configure

SNMP and remote management.

Diagnostic This link takes you to screens where you can ping IP addresses, run traceroute, test port(s).

System Log This link takes you to a screen where you can view system logs.

Syslog Setup This link takes you to a screen where you can setup system logs and a system log server.

Cluster

Management

This link takes you to a screen where you can configure clustering management and view its

status.

MAC Table This link takes you to a screen where you can view the MAC address and VLAN ID of a device

attach to a port. You can also view what kind of MAC address it is.

ARP Table This link takes you to a screen where you can view the MAC address – IP address resolution

table.

Path MTU Table This link takes you to a screen where you can view the IPv6 path MTU table.

Configure Clone This link takes you to a screen where you can copy attributes of one port to (an)other port(s).

IPv6 Neighbor

Table

This link takes you to a screen where you can view the Switch’s IPv6 neighbor table.

Port Status This link takes you to a screen where you can view the port statistics.

Table 9 Navigation Panel Links (continued)

LINK DESCRIPTION

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4.5 Saving Your Configuration

When you are done modifying the settings in a screen, click Apply to save your changes back to the

run-time memory. Settings in the run-time memory are lost when the Switch’s power is turned off.

Click the Save link in the upper right hand corner of the web configurator to save your configuration to

nonvolatile memory. Nonvolatile memory refers to the Switch’s storage that remains even if the Switch’s

power is turned off.

Note: Use the Save link when you are done with a configuration session.

4.6 Switch Lockout

You could block yourself (and all others) from using in-band-management (managing through the data

ports) if you do one of the following:

1Delete the management VLAN (default is VLAN 1).

2Delete all port-based VLANs with the CPU port as a member. The “CPU port” is the management port of

the Switch.

3Filter all traffic to the CPU port.

4Disable all ports.

5Misconfigure the text configuration file.

6Forget the password and/or IP address.

7Prevent all services from accessing the Switch.

8Change a service port number but forget it.

9You forgot to log out of the Switch from a computer before logging in again on another computer.

Note: Be careful not to lock yourself and others out of the Switch.

4.7 Resetting the Switch

If you lock yourself (and others) from the Switch or forget the administrator password, you will need to

reload the factory-default configuration file or reset the Switch back to the factory defaults.

4.7.1 Using the RESTORE Button

See Table 3 on page 36 to see how to use the RESTORE button to restore the factory default file.

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4.7.2 Reload the Configuration File

Uploading the factory-default configuration file replaces the current configuration file with the factory-

default configuration file. This means that you will lose all previous configurations and the speed of the

console port will be reset to the default of 115200 bps with 8 data bit, no parity, one stop bit and flow

control set to none. The password will also be reset to “1234” and the IP address to 192.168.1.1 or DHCP-

assigned IP.

To upload the configuration file, do the following:

1Connect to the console port using a computer with terminal emulation software. See Section 3.2 on

page 39 for details.

2Disconnect and reconnect the Switch’s power to begin a session. When you reconnect the Switch’s

power, you will see the initial screen.

3When you see the message “Press any key to enter Debug Mode within 3 seconds ...” press

any key to enter debug mode.

4Type atlc after the “Enter Debug Mode” message.

5Wait for the “Starting XMODEM upload” message before activating XMODEM upload on your

terminal.

6After a configuration file upload, type atgo to restart the Switch.

Figure 40 Resetting the Switch: Via the Console Port

The Switch is now reinitialized with a default configuration file including the default password of “1234”.

4.8 Logging Out of the Web Configurator

Click Logout in a screen to exit the web configurator. You have to log in with your password again after

you log out. This is recommended after you finish a management session for security reasons.

Bootbase Version: V1.00 | 02/21/2016 15:43:29

RAM: Size = 1048576 Kbytes

FLASH: 64M

ZyNOS Version: V4.60(ABML.0) | 04/18/2017 11:41:8

Press any key to enter debug mode within 1 second.

.....................................

Enter Debug Mode

ras> atlc

Starting XMODEM upload (CRC mode)....

CCCCCCCCCCCCCCCC

Total 393216 bytes received.

Erasing..

................................................................

ras> atgo

Chapter 4 The Web Configurator

GS2220 Series User’s Guide

Figure 41 Web Configurator: Logout Screen

4.9 Help

The web configurator’s online help has descriptions of individual screens and some supplementary

information.

Click the Help link from a web configurator screen to view an online help description of that screen.

GS2220 Series User’s Guide

CHAPTER 5

Initial Setup Example

5.1 Overview

This chapter shows how to set up the Switch for an example network.

The following lists the configuration steps for the initial setup:

•Creating a VLAN

•Setting Port VID

•Configuring Switch Management IP Address

5.1.1 Creating a VLAN

VLANs confine broadcast frames to the VLAN group in which the port(s) belongs. You can do this with

port-based VLAN or tagged static VLAN with fixed port members.

In this example, you want to configure port 1 as a member of VLAN 2.

Figure 42 Initial Setup Network Example: VLAN

1Click Advanced Application > VLAN > VLAN Configuration in the navigation panel and click the Static

VLAN Setup link.

Chapter 5 Initial Setup Example

GS2220 Series User’s Guide

2In the Static VLAN screen, select ACTIVE, enter a descriptive name in the Name field and enter 2 in the

VLAN Group ID field for the VLAN2 network.

Note: The VLAN Group ID field in this

screen and the VID field in the IP

Setup screen refer to the same

VLAN ID.

3Since the VLAN2 network is connected to port 1 on the Switch, select Fixed to configure port 1 to be a

permanent member of the VLAN only.

4To ensure that VLAN-unaware devices (such as computers and hubs) can receive frames properly, clear

the TX Tagging check box to set the Switch to remove VLAN tags before sending.

5Click Add to save the settings to the run-time memory. Settings in the run-time memory are lost when the

Switch’s power is turned off.

5.1.2 Setting Port VID

Use PVID to add a tag to incoming untagged frames received on that port so that the frames are

forwarded to the VLAN group that the tag defines.

In the example network, configure 2 as the port VID on port 1 so that any untagged frames received on

that port get sent to VLAN 2.

Chapter 5 Initial Setup Example

GS2220 Series User’s Guide

Figure 43 Initial Setup Network Example: Port VID

1Click Advanced Applications > VLAN > VLAN

Configuration in the navigation panel. Then

click the VLAN Port Setup link.

2Enter 2 in the PVID field for port 1 and click

Apply to save your changes back to the run-

time memory. Settings in the run-time memory

are lost when the Switch’s power is turned off.

5.1.3 Configuring Switch Management IP Address

If the Switch fails to obtain an IP address from a DHCP server, the Switch will use 192.168.1.1 as the

management IP address. You can configure another IP address in a different subnet for management

purposes. The following figure shows an example.

Chapter 5 Initial Setup Example

GS2220 Series User’s Guide

Figure 44 Initial Setup Example: Management IP Address

1Connect your computer to any Ethernet port on the Switch. Make sure your computer is in the same

subnet as the Switch.

2Open your web browser and enter 192.168.1.1 (the default IP address) in the address bar to access the

web configurator. See Section 4.2 on page 43 for more information.Click Basic Setting > IP Setup in the

navigation panel.

3Configure the related fields in the IP Setup screen.

4For the VLAN2 network, enter 192.168.2.1 as the IP address and 255.255.255.0 as the subnet mask.

5In the VID field, enter the ID of the VLAN group to which you want this management IP address to

belong. This is the same as the VLAN ID you configure in the Static VLAN screen.

GS2220 Series User’s Guide

CHAPTER 6

Tutorials

6.1 Overview

This chapter provides some examples of using the web configurator to set up and use the Switch. The

tutorials include:

•How to Use DHCPv4 Snooping on the Switch

•How to Use DHCPv4 Relay on the Switch

•How to Use Auto Configuration via a DHCP Server on the Switch

6.2 How to Use DHCPv4 Snooping on the Switch

You only want DHCP server A connected to port 5 to assign IP addresses to all devices in VLAN network

(V). Create a VLAN containing ports 5, 6 and 7. Connect a computer M to the Switch for management.

Figure 45 Tutorial: DHCP Snooping Tutorial Overview

Note: For related information about DHCP snooping, see Section 26.5 on page 242.

The settings in this tutorial are as the following.

1Access the Switch through http://192.168.1.1 by default. Log into the Switch by entering the username

(default: admin) and password (default: 1234).

Table 10 Tutorial: Settings in this Tutorial

HOST PORT CONNECTED VLAN PVID DHCP SNOOPING PORT TRUSTED

DHCP Server (A) 5 1 and 100 100 Yes

DHCP Client (B) 6 1 and 100 100 No

DHCP Client (C) 7 1 and 100 100 No

Chapter 6 Tutorials

GS2220 Series User’s Guide

2Go to Advanced Application > VLAN > VLAN Configuration > Static VLAN Setup, and create a VLAN with

ID of 100. Add ports 5, 6 and 7 in the VLAN by selecting Fixed in the Control field as shown.

Deselect Tx Tagging because you don’t want outgoing traffic to contain this VLAN tag.

Click Add.

Figure 46 Tutorial: Create a VLAN and Add Ports to It

3Go to Advanced Application > VLAN > VLAN Configuration > VLAN Port Setup, and set the PVID of the

ports 5, 6 and 7 to 100. This tags untagged incoming frames on ports 5, 6 and 7 with the tag 100.

Figure 47 Tutorial: Tag Untagged Frames

Chapter 6 Tutorials

GS2220 Series User’s Guide

4Go to Advanced Application > IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping >

Configure, activate and specify VLAN 100 as the DHCP VLAN as shown. Click Apply.

Figure 48 Tutorial: Specify DHCP VLAN

5Click the Port link at the top right corner.

6The DH CP Snooping Port Configure screen appears. Select Trusted in the Server Trusted state field for port

5 because the DHCP server is connected to port 5. Keep ports 6 and 7 Untrusted because they are

connected to DHCP clients. Click Apply.

Figure 49 Tutorial: Set the DHCP Server Port to Trusted

Chapter 6 Tutorials

GS2220 Series User’s Guide

7Go to Advanced Application > IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping >

Configure > VLAN, show VLAN 100 by entering 100 in the Start VID and End VID fields and click Apply.

Then select Yes in the Enabled field of the VLAN 100 entry shown at the bottom section of the screen.

If you want to add more information in the DHCP request packets such as source VLAN ID or system

name, you can also select an Option82 Profile in the entry. See Section 26.17.1.3 on page 264.

Figure 50 Tutorial: Enable DHCP Snooping on this VLAN

8Click Save at the top right corner of the web configurator to save the

configuration permanently.

9Connect your DHCP server to port 5 and a computer (as DHCP client) to either port 6 or 7. The computer

should be able to get an IP address from the DHCP server. If you put the DHCP server on port 6 or 7, the

computer will not able to get an IP address.

10 To check if DHCP snooping works, go to Advanced Application > IP Source Guard > IPv4 Source Guard

Setup, you should see an IP assignment with the type DHCP-Snooping as shown.

Figure 51 Tutorial: Check the Binding If DHCP Snooping Works

You can also telnet. Use the command “show dhcp snooping binding” to see the DHCP snooping

binding table as shown next.

6.3 How to Use DHCPv4 Relay on the Switch

This tutorial describes how to configure your Switch to forward DHCP client requests to a specific DHCP

server. The DHCP server can then assign a specific IP address based on the information in the DHCP

requests.

sysname# show dhcp snooping binding

MacAddress IpAddress Lease Type VLAN Port

----------------- --------------- ------------ ------------- ---- -----

00:02:00:00:00:1c 10.10.1.16 6d23h59m20s dhcp-snooping 100 7

Total number of bindings: 1

Chapter 6 Tutorials

GS2220 Series User’s Guide

6.3.1 DHCP Relay Tutorial Introduction

In this example, you have configured your DHCP server (192.168.2.3) and want to have it assign a

specific IP address (say 172.16.1.18) to DHCP client A based on the system name, VLAN ID and port

number in the DHCP request. Client A connects to the Switch’s port 2 in VLAN 102.

Figure 52 Tutorial: DHCP Relay Scenario

6.3.2 Creating a VLAN

Follow the steps below to configure port 2 as a member of VLAN 102.

1Access the web configurator through the Switch’s management port.

2Go to Basic Setting > Switch Setup and set the VLAN type to 802.1Q. Click Apply to save the settings to

the run-time memory.

Figure 53 Tutorial: Set VLAN Type to 802.1Q

Chapter 6 Tutorials

GS2220 Series User’s Guide

3Click Advanced Application > VLAN > VLAN Configuration > Static VLAN Setup.

4In the Static VLAN screen, select ACTIVE, enter a descriptive name (VLAN 102 for example) in the Name

field and enter 102 in the VLAN Group ID field.

5Select Fixed to configure port 2 to be a permanent member of this VLAN.

6Clear the TX Tagging check box to set the Switch to remove VLAN tags before sending.

7Click Add to save the settings to the run-time memory. Settings in the run-time memory are lost when the

Switch’s power is turned off.

Figure 54 Tutorial: Create a Static VLAN

8Click the VLAN Configuration link in the Static VLAN Setup screen and then the VLAN Port Setup link in the

VLAN Configuration screen.

Figure 55 Tutorial: Click the VLAN Port Setting Link

9Enter 102 in the PVID field for port 2 to add a tag to incoming untagged frames received on that port so

that the frames are forwarded to the VLAN group that the tag defines.

10 Click Apply to save your changes back to the run-time memory.

Chapter 6 Tutorials

GS2220 Series User’s Guide

Figure 56 Tutorial: Add Tag for Frames Received on Port 2

11 Click the Save link in the upper right corner of the web configurator to save your configuration

permanently.

6.3.3 Configuring DHCPv4 Relay

Follow the steps below to enable DHCP relay on the Switch and allow the Switch to add relay agent

information (such as the VLAN ID) to DHCP requests.

1Click IP Application > DHCP > DHCPv4 and then the Global link to open the DHCP Relay screen.

2Select the Active check box.

3Enter the DHCP server’s IP address (192.168.2.3 in this example) in the Remote DHCP Server 1 field.

4Select default1 or default2 in the Option 82 Profile field.

5Click Apply to save your changes back to the run-time memory.

Figure 57 Tutorial: Set DHCP Server and Relay Information

6Click the Save link in the upper right corner of the web configurator to save your configuration

permanently.

7The DHCP server can then assign a specific IP address based on the DHCP request.

Chapter 6 Tutorials

GS2220 Series User’s Guide

6.3.4 Troubleshooting

Check the client A’s IP address. If it did not receive the IP address 172.16.1.18, make sure:

1Client A is connected to the Switch’s port 2 in VLAN 102.

2You configured the correct VLAN ID, port number and system name for DHCP relay on both the DHCP

server and the Switch.

3You clicked the Save link on the Switch to have your settings take effect.

6.4 How to Use Auto Configuration via a DHCP Server on

the Switch

Follow the steps below to set up configurations on a DHCP server, TFTP server, and the Switch, so you

can load an auto configuration file automatically from a TFTP server when you reboot the Switch.

Note that you can set up a DHCP server and TFTP server either on the same device or different devices.

Also, make sure the Switch can communicate with the TFTP server.

Note: Steps order could vary according to different programs you use.

Note: You need to set up configurations on a DHCP server and TFTP server first to use auto

configuration.

Setting up a DHCP Server

1Set up a dynamic IP addresses pool so the DHCP server will assign an IP address to the Switch in that

range.

2Set up a TFTP server IP address, so the Switch will know where to load the auto configuration file.

3Set up the filename of the auto configuration file, so the Switch will know which file to load when you

reboot the Switch.

• Enter the filename of an auto configuration file. The Switch will load this auto configuration file

when rebooting with DHCP option 60 disabled.

• If you want to load the auto configuration file with DHCP option 60 enabled and a Vendor Class

Identifier assigned when you reboot the Switch, follow the instruction below. Otherwise, skip this

step.

Enter the filename of the an auto configuration file. Set up a Vendor Class Identifier. To have the

Switch load this auto configuration file, two conditions listed above must be met. Please refer to

the following steps to see how to set up a Vendor Class Identifier on the Switch.

Setting up a TFTP Server

1Select a directory on the TFTP server.

2Put the configuration files in that directory.

Chapter 6 Tutorials

GS2220 Series User’s Guide

Setting up the Switch

1Open the web configurator. Go to the Management > Maintenance screen, and click the Click Here

button next to the Auto Configuration field.

Figure 58 Tutorial: Auto Configuration Screen

2Select the check box in the Active field to enable auto configuration. Select DHCP in the Mode field,

Click Apply to save your changes. See Section 43.9 on page 365 for more information about auto

configuration.

Figure 59 Tutorial: Enable Auto Configuration

3You need to save the current configuration in a configuration file, so the Switch will load the auto

configuration file from the TFTP server automatically when rebooting. Go to the Management >

Maintenance screen. Click the Config 1, Config2, or Custom Default button next to the Save

Configuration field. See Section 43.4 on page 360 for more information.

4Click the same button next to Reboot System field to reboot the Switch, and load the auto configuration

setting as configured before. For example, if you save the auto configuration setting to Config 1, you

need to click the Config 1 button next to the Reboot System field. See Section 43.5 on page 361 for more

information.

Chapter 6 Tutorials

GS2220 Series User’s Guide

Figure 60 Tutorial: Save Configuration & Reboot System

5Go to the Management > System Log screen to see if auto configuration was performed successfully.

Figure 61 Tutorial: Log

6Check the screens to see if it’s the configuration file you want to load. If it’s not, go through the steps

above to check your configurations. If it is, click Save at the top right corner of the web configurator to

save the configuration permanently.

Figure 62 Tutorial: Save

PART II

Technical Reference

GS2220 Series User’s Guide

CHAPTER 7

Status

7.1 Overview

This chapter describes the screens for System Status and Neighbor.

7.1.1 What You Can Do

• Use the Status screen (Section 7.2 on page 74) to see the Switch’s general device information, system

status, and IP addresses. You can also display other status screens for more information.

• Use the Neighbor screen (Section 7.2.1 on page 76) to view and manage Switch’s neighbor devices.

7.2 Status

The Status screen displays when you log into the Switch or click Status at the top right corner of the web

configurator. The Status screen displays general device information, system status, and its IP addresses.

Figure 63 Status

Chapter 7 Status

GS2220 Series User’s Guide

The following table describes the labels in this screen.

Table 11 Status

LABEL DESCRIPTION

Device Information

Device Type This field displays the model name of this Switch.

System Name This field displays the name used to identify the Switch on any network.

Boot Version This field displays the version number and date of the boot module that is currently on the

Switch.

System Location This field displays the geographic location of your Switch. You can change the setting in the

Basic Setting > General Setup screen.

Firmware

Version

This field displays the version number and date of the firmware the Switch is currently running.

System Time This field displays the current date and time in the Switch. The format is mm-dd-yyyy hh:mm:ss.

Hardware

Version

This field displays the hardware version number of the Switch. The integer is the generation

number of the Switch series, and the decimal is the version of the hardware change. For

example, V1.0 is a hardware version for the Switch where 1 identifies the first generation of the

Switch series, and .0 is the first hardware change.

System Up Time This field displays how long the Switch has been running since it last restarted or was turned on.

MAC Address This field displays the MAC addresses of the Switch.

times out. After it times out you have to log in with your password again.

Serial Number This field displays the serial number of this Switch. The serial number is used for device tracking

and control.

Registration

MAC Address

This field displays the MAC address of the Switch that you must use to register at myZyxel or the

NCC (Nebula Control Center).

Hybrid Mode This field displays whether the Switch is in Standalone mode or Cloud mode. In Standalone mode

you can see a link to a QR code to register the Switch to use NCC (Nebula Control Center).

Cloud Control

Status

This field displays the registration and connection status between the Switch and the NCC

(Nebula Control Center). See Section 3.3 on page 41 for more information on the Cloud LED.

In Standalone mode, the status will display Disconnected or Unregistered. In Cloud mode the

status will display Connected or Disconnected.

Connected - The Switch is registered with and connected to the NCC.

Disconnected - The Switch is not connected to the NCC.

Unregistered - The Switch is not registered with the NCC.

PoE Usage This field displays the amount of power the Switch is currently supplying to the connected PoE-

enabled devices and the total power the Switch can provide to the connected PDs. It also

shows the percentage of PoE power usage.

When PoE usage reaches 100%, the Switch will shut down PDs one-by-one according to the PD

priority which you configured in Basic Setting > PoE Setup.

Detail Click this link to go to the Basic Setting > System Info screen to check other detailed information,

such as system resource usage and the Switch temperature, fan speeds or voltage.

IP Address Information

IPv4 Address This field displays the Switch’s current IPv4 address.

Subnet Mask This field displays the Switch’s subnet mask.

Default

Gateway

This field displays the IP address of the Switch’s default gateway.

IP Setup Click the link to go to the Basic Setting > IP Setup screen.

Chapter 7 Status

GS2220 Series User’s Guide

7.2.1 Neighbor Screen

The Neighbor screen allows you to view and manage the Switch’s neighboring devices more

conveniently. It uses Layer Link Discovery Protocol (LLDP) to discover all neighbor devices connected to

the Switch including non-Zyxel devices. You can perform tasks on the neighboring devices like login,

reboot (turn the power off and then back on again), and reset to factory default settings in the

Neighbor screen. For more information on LLDP, see Section 34.1 on page 295.

Click Status > Neighbor to see the following screen.

Figure 64 Status > Neighbor

The following table describes the fields in the above screen.

IPV6 Global

Unicast Address

This field displays the Switch’s IPv6 global unicast address

IPV6 Link-Local

Address

This field displays the Switch’s IPv6 link-local address.

IPv6

configuration

Click the link to go to the Basic Setting > IPv6 screen.

Device Status

and Quick

Configuration

This section shows whether a feature is enabled or not on the Switch. You can click a feature’s

Setting link to go to the configuration screen for the feature.

Hover your cursor over a red exclamation mark to display information about the feature.

Quick Links This section provides the shortcut link to a specific configuration screen.

Table 11 Status (continued)

LABEL DESCRIPTION

Table 12 Status > Neighbor

LABEL DESCRIPTION

Port This shows the port of the Switch, on which the neighboring device is discovered.

Port Name This shows the port description of the Switch.

Link This shows the speed (either 100M for 100Mbps or 1G for 1 Gbps) and the duplex (F for full

duplex or H for half). This field displays Down if the port is not connected to any device.

PoE Draw (W) This shows the consumption that the neighboring device connected to this port draws from

the Switch. This allows you to plan and use within the power budget of the Switch.

System Name This shows the system name of the neighbor device.

Chapter 7 Status

GS2220 Series User’s Guide

7.2.2 Neighbor Detail

Use this screen to view detailed information about the neighboring devices. Device information is

displayed in gray when the neighboring device is currently offline.

Up to 10 neighboring device records per Ethernet port can be retained in this screen even when the

devices are offline. When the maximum number of neighboring device records per Ethernet port is

reached, new device records automatically overwrite existing offline device records, starting with the

oldest existing offline device record first.

Click the Neighbor Detail link in the Status > Neighbor screen to see the following screen.

IP This shows the IP address of the neighbor device. The IP address is a hyper link that you can

click to log into and manage the neighbor device through its web configurator.

PWR Cycle Click the Cycle button to turn OFF the power of the neighboring device and turn it back ON

again. A count down button (from 5 to 0) starts.

Note: The Cycle button is clickable only when the neighboring device is a powered

device (PD) and able to receive power from the Switch.

Reset to Default Click the Reset button to reset the neighbor device to its factory default settings. A warning

message “Are you sure you want to load factory default?” appears prompting you to confirm

the action. After confirming the action a count down button (from 5 to 0) starts.

Note:

• The Switch must be a Power Sourcing Equipment (PSE) and the neighboring device is a

powered device (PD).

• If multiple neighbor devices use the same port, the Reset button is not available and will

show “-” instead.

• You can only reset Zyxel powered devices that support the ZON utility.

Select an entry’s check box to select a specific port. Otherwise, select the check box in the

table heading row to select all ports.

Flush Click the Flush button to remove information about neighbors learned on the selected ports.

Table 12 Status > Neighbor

LABEL DESCRIPTION

Chapter 7 Status

GS2220 Series User’s Guide

Figure 65 Status > Neighbor > Neighbor Detail

The following table describes the fields in the above screen.

Table 13 Status > Neighbor > Neighbor Detail

LABEL DESCRIPTION

Local Port This shows the port of the Switch, on which the neighboring device is discovered.

Desc. This shows the port description of the Switch.

Link This shows the speed (either 100M for 100Mbps or 1G for 1 Gbps) and the duplex (F for full

duplex or H for half). This field displays Down if the port is not connected to any device.

PoE Draw (W) This shows the consumption that the neighboring device connected to this port draws from the

Switch. This allows you to plan and use within the power budget of the Switch.

PWR Cycle Click the Cycle button to turn OFF the power of the neighboring device and turn it back ON

again. A count down button (from 5 to 0) starts.

Note: The Cycle button is clickable only when the neighboring device is a powered

device (PD) and able to receive power from the Switch.

Remote

System Name This shows the system name of the neighbor device.

Model This shows the model name of the neighbor device. This field will show “--” for devices that do

not support the ZON utility.

Firmware This shows the firmware version of the neighbor device. This field will show “--” for devices that

do not support the ZON utility.

IP This shows the IP address of the neighbor device. The IP address is a hyper link that you can click

to log into and manage the neighbor device through its web configurator.

Port This shows the number of the neighbor device’s port which is connected to the Switch.

Desc. This shows the description of the neighbor device’s port which is connected to the Switch.

Location This shows the geographic location of the neighbor device. This field will show “--” for devices

that do not support the ZON utility.

Chapter 7 Status

GS2220 Series User’s Guide

MAC This shows the MAC address of the neighbor device.

Reset to Default Click the Reset button to reset the neighboring device to its factory default settings. A warning

message “Are you sure you want to load factory default?” appears, prompting you to confirm

the action. After confirming the action a count down button (from 5 to 0) starts.

Note:

• The Switch must be a Power Sourcing Equipment (PSE) and the neighboring device is a

powered device (PD).

• If multiple neighbor devices use the same port, the Reset button is not available.

• You can only reset Zyxel powered devices that support the ZON utility.

Table 13 Status > Neighbor > Neighbor Detail (continued)

LABEL DESCRIPTION

GS2220 Series User’s Guide

CHAPTER 8

Basic Setting

8.1 Overview

This chapter describes how to configure the System Info, General Setup, Switch Setup, IP Setup, Port

Setup, PoE Setup, Interface Setup, IPv6, DNS and Cloud Management screens.

8.1.1 What You Can Do

• Use the System Info screen (Section 8.2 on page 80) to check the firmware version number and

monitor the Switch temperature, fan speeds and voltage.

• Use the General Setup screen (Section 8.3 on page 82) to configure general settings such as the

system name and time.

• Use the Switch Setup screen (Section 8.5 on page 85) to choose your VLAN type, set the GARP timers

and assign priorities to queues.

• Use the IP Setup screen (Section 8.6 on page 86) to configure the Switch IP address, default gateway

device, and the management VLAN ID.

• Use the Port Setup screen (Section 8.7 on page 88) to configure Switch port settings.

• Use the PoE Setup screens (Section 8.8 on page 90) to view the current amount of power that PDs are

receiving from the Switch and set the priority levels for the Switch in distributing power to PDs. This

screen is available for PoE model(s) only.

• Use the Interface Setup screens (Section 8.9 on page 96) to configure Switch interface type and

interface ID settings.

• Use the IPv6 screens (Section 8.10 on page 97) to view IPv6 status and IPv6 configuration.

• Use the DNS screen (Section 8.11 on page 107) to configure the default domain name server.

• Use the Cloud Management screen (Section 8.12 on page 107) to display links to Nebula Control

Center Discovery and Nebula Switch Registration screens.

8.2 System Information

In the navigation panel, click Basic Setting > System Info to display the screen as shown. Use this screen

to view general system information. You can check the firmware version number and monitor the Switch

temperature, fan speeds and voltage in this screen.

Chapter 8 Basic Setting

GS2220 Series User’s Guide

Figure 66 Basic Setting > System Info

The following table describes the labels in this screen.

Table 14 Basic Setting > System Info

LABEL DESCRIPTION

System Name This field displays the descriptive name of the Switch for identification purposes.

Product Model This field displays the product model of the Switch. Use this information when searching for

firmware upgrade or looking for other support information in the website.

ZyNOS F/W

Version

This field displays the version number of the Switch 's current firmware including the date created.

Ethernet

Address

This field refers to the Ethernet MAC (Media Access Control) address of the Switch.

CPU Utilization CPU utilization quantifies how busy the system is. Current (%) displays the current percentage of

CPU utilization.

Memory

Utilization

Memory utilization shows how much DRAM memory is available and in use. It also displays the

current percentage of memory utilization.

Name This field displays the name of memory pool.

Total (byte) This field displays the total number of bytes in this memory pool.

Used (byte) This field displays the number of bytes being used in this memory pool.

Utilization

(%) This field displays the percentage (%) of memory being used in this memory pool.

Hardware Monitor

Temperature

Unit

The Switch has temperature sensors that are capable of detecting and reporting if the

temperature rises above the threshold. You may choose the temperature unit (Centigrade or

Fahrenheit) in this field.

Chapter 8 Basic Setting

GS2220 Series User’s Guide

8.3 General Setup

Use this screen to configure general settings such as the system name and time. Click Basic Setting >

General Setup in the navigation panel to display the screen as shown.

Temperature

(C)

BOARD, MAC and PHY refer to the location of the temperature sensors on the Switch printed

circuit board.

Current This shows the current temperature at this sensor.

MAX This field displays the maximum temperature measured at this sensor.

MIN This field displays the minimum temperature measured at this sensor.

Threshold This field displays the upper temperature limit at this sensor.

Status This field displays Normal for temperatures below the threshold and Error for those above.

FAN Speed

(RPM)

A properly functioning fan is an essential component (along with a sufficiently ventilated, cool

operating environment) in order for the device to stay within the temperature threshold. Each fan

has a sensor that is capable of detecting and reporting if the fan speed falls below the threshold

shown.

Current This field displays this fan's current speed in Revolutions Per Minute (RPM).

MAX This field displays this fan's maximum speed measured in Revolutions Per Minute (RPM).

MIN This field displays this fan's minimum speed measured in Revolutions Per Minute (RPM). "<41" is

displayed for speeds too small to measure (under 2000 RPM).

Threshold This field displays the minimum speed at which a normal fan should work.

Status Normal indicates that this fan is functioning above the minimum speed. Error indicates that this

fan is functioning below the minimum speed.

Voltage(V) The power supply for each voltage has a sensor that is capable of detecting and reporting if the

voltage falls out of the tolerance range.

Current This is the current voltage reading.

MAX This field displays the maximum voltage measured at this point.

MIN This field displays the minimum voltage measured at this point.

Threshold This field displays the percentage tolerance of the voltage with which the Switch still works.

Status Normal indicates that the voltage is within an acceptable operating range at this point;

otherwise Error is displayed.

Table 14 Basic Setting > System Info (continued)

LABEL DESCRIPTION

Chapter 8 Basic Setting

GS2220 Series User’s Guide

Figure 67 Basic Setting > General Setup

The following table describes the labels in this screen.

Table 15 Basic Setting > General Setup

LABEL DESCRIPTION

System Name Choose a descriptive name for identification purposes. This name consists of up to 64 printable

characters; spaces are allowed.

Location Enter the geographic location of your Switch. You can use up to 128 printable ASCII

characters; spaces are allowed.

Contact Person's

Name

Enter the name of the person in charge of this Switch. You can use up to 32 printable ASCII

characters; spaces are allowed.

Use Time Server

when Bootup

Enter the time service protocol that your time server uses. Not all time servers support all

protocols, so you may have to use trial and error to find a protocol that works. The main

differences between them are the time format.

When you select the Daytime (RFC 867) format, the Switch displays the day, month, year and

time with no time zone adjustment. When you use this format it is recommended that you use a

Daytime timeserver within your geographical time zone.

Time (RFC-868) format displays a 4-byte integer giving the total number of seconds since 2016/

1/1 at 0:0:0.

NTP (RFC-1305) is similar to Time (RFC-868).

None is the default value. Enter the time manually. Each time you turn on the Switch, the time

and date will be reset to 2016-1-1 0:0:0.

Time Server IP

Address

Enter the IP address or domain name of your timeserver. The Switch searches for the timeserver

for up to 60 seconds. If you select a timeserver that is unreachable, then this screen will appear

locked for 60 seconds. Please wait.

Time Server Sync

Interval

Enter the frequency you would like the Zyxel Device to sync with the NTP server.

Current Time This field displays the time you open this menu (or refresh the menu).

New Time

(hh:min:ss)

Enter the new time in hour, minute and second format. The new time then appears in the

Current Time field after you click Apply.

Current Date This field displays the date you open this menu.

Chapter 8 Basic Setting

GS2220 Series User’s Guide

8.4 Introduction to VLANs

A VLAN (Virtual Local Area Network) allows a physical network to be partitioned into multiple logical

networks. Devices on a logical network belong to one group. A device can belong to more than one

group. With VLAN, a device cannot directly talk to or hear from devices that are not in the same

group(s); the traffic must first go through a router.

In MTU (Multi-Tenant Unit) applications, VLAN is vital in providing isolation and security among the

subscribers. When properly configured, VLAN prevents one subscriber from accessing the network

resources of another on the same LAN, thus a user will not see the printers and hard disks of another user

in the same building.

VLAN also increases network performance by limiting broadcasts to a smaller and more manageable

logical broadcast domain. In traditional switched environments, all broadcast packets go to each and

every individual port. With VLAN, all broadcasts are confined to a specific broadcast domain.

New Date (yyyy-

mm-dd)

Enter the new date in year, month and day format. The new date then appears in the Current

Date field after you click Apply.

Time Zone Select the time difference between UTC (Universal Time Coordinated, formerly known as GMT,

Greenwich Mean Time) and your time zone from the drop-down list box.

Daylight Saving

Time

Daylight saving is a period from late spring to early fall when many countries set their clocks

ahead of normal local time by one hour to give more daytime light in the evening.

Select this option if you use Daylight Saving Time.

Start Date Configure the day and time when Daylight Saving Time starts if you selected Daylight Saving

Time. The time is displayed in the 24 hour format. Here are a couple of examples:

Daylight Saving Time starts in most parts of the United States on the second Sunday of March.

Each time zone in the United States starts using Daylight Saving Time at 2 A.M. local time. So in

the United States you would select Second, Sunday, March and 2:00.

Daylight Saving Time starts in the European Union on the last Sunday of March. All of the time

zones in the European Union start using Daylight Saving Time at the same moment (1 A.M. GMT

or UTC). So in the European Union you would select Last, Sunday, March and the last field

depends on your time zone. In Germany for instance, you would select 2:00 because

Germany's time zone is one hour ahead of GMT or UTC (GMT+1).

End Date Configure the day and time when Daylight Saving Time ends if you selected Daylight Saving

Time. The time field uses the 24 hour format. Here are a couple of examples:

Daylight Saving Time ends in the United States on the first Sunday of November. Each time

zone in the United States stops using Daylight Saving Time at 2 A.M. local time. So in the United

States you would select First, Sunday, November and 2:00.

Daylight Saving Time ends in the European Union on the last Sunday of October. All of the time

zones in the European Union stop using Daylight Saving Time at the same moment (1 A.M. GMT

or UTC). So in the European Union you would select Last, Sunday, October and the last field

depends on your time zone. In Germany for instance, you would select 2:00 because

Germany's time zone is one hour ahead of GMT or UTC (GMT+1).

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 15 Basic Setting > General Setup (continued)

LABEL DESCRIPTION

Chapter 8 Basic Setting

GS2220 Series User’s Guide

Note: VLAN is unidirectional; it only governs outgoing traffic.

See Chapter 9 on page 110 for information on port-based and 802.1Q tagged VLANs.

8.5 Switch Setup

Click Basic Setting > Switch Setup in the navigation panel to display the screen as shown. The VLAN

setup screens change depending on whether you choose 802.1Q or Port Based in the VLAN Type field in

this screen. Refer to Chapter 9 on page 110 for more information on VLAN.

Figure 68 Basic Setting > Switch Setup

The following table describes the labels in this screen.

Table 16 Basic Setting > Switch Setup

LABEL DESCRIPTION

VLAN Type Choose 802.1Q or Port Based. The VLAN Setup screen changes depending on whether you

choose 802.1Q VLAN type or Port Based VLAN type in this screen. See Chapter 9 on page 110 for

more information.

MAC Address

Learning

MAC address learning reduces outgoing traffic broadcasts. For MAC address learning to occur

on a port, the port must be active.

Aging Time Enter a time from 10 to 1000000 seconds. This is how long all dynamically learned MAC

addresses remain in the MAC address table before they age out (and must be relearned).

ARP Aging Time

Aging Time Enter a time from 60 to 1000000 seconds. This is how long dynamically learned ARP entries

remain in the ARP table before they age out (and must be relearned). The setting here applies

to ARP entries which are newly added in the ARP table after you click Apply.

GARP Timer: Switches join VLANs by making a declaration. A declaration is made by issuing a Join message using

GARP. Declarations are withdrawn by issuing a Leave message. A Leave All message terminates all registrations.

GARP timers set declaration timeout values. See the chapter on VLAN setup for more background information.

Join Timer Join Timer sets the duration of the Join Period timer for GVRP in milliseconds. Each port has a Join

Period timer. The allowed Join Time range is between 100 and 65535 milliseconds; the default is

200 milliseconds. See the chapter on VLAN setup for more background information.

Chapter 8 Basic Setting

GS2220 Series User’s Guide

8.6 IP Setup

Use the IP Setup screen to configure the Switch IP address, default gateway device, and the

management VLAN ID. The default gateway specifies the IP address of the default gateway (next hop)

for outgoing traffic.

8.6.1 Management IP Addresses

The Switch needs an IP address for it to be managed over the network. When the Switch fails to obtain

an IP address from a DHCP server, the static IP address 192.168.1.1 will be automatically added and

used as the Switch’s management IP address.

You can configure up to 64 IP addresses which are used to access and manage the Switch from the

ports belonging to the pre-defined VLAN(s).

Note: You must configure a VLAN first. Each VLAN can only have one management IP

address.

Leave Timer Leave Time sets the duration of the Leave Period timer for GVRP in milliseconds. Each port has a

single Leave Period timer. Leave Time must be two times larger than Join Timer; the default is 600

milliseconds.

Leave All Timer Leave All Timer sets the duration of the Leave All Period timer for GVRP in milliseconds. Each port

has a single Leave All Period timer. Leave All Timer must be larger than Leave Timer.

Priority Queue Assignment

IEEE 802.1p defines up to eight separate traffic types by inserting a tag into a MAC-layer frame that contains bits to

define class of service. Frames without an explicit priority tag are given the default priority of the ingress port. Use

the next fields to configure the priority level-to-physical queue mapping.

The Switch has eight physical queues that you can map to the 8 priority levels. On the Switch, traffic assigned to

higher index queues gets through faster while traffic in lower index queues is dropped if the network is congested.

Priority Level (The following descriptions are based on the traffic types defined in the IEEE 802.1d standard (which

incorporates the 802.1p).

Priority 7 Typically used for network control traffic such as router configuration messages.

Priority 6 Typically used for voice traffic that is especially sensitive to jitter (jitter is the variations in delay).

Priority 5 Typically used for video that consumes high bandwidth and is sensitive to jitter.

Priority 4 Typically used for controlled load, latency-sensitive traffic such as SNA (Systems Network

Architecture) transactions.

Priority 3 Typically used for “excellent effort” or better than best effort and would include important

business traffic that can tolerate some delay.

Priority 2 This is for “spare bandwidth”.

Priority 1 This is typically used for non-critical “background” traffic such as bulk transfers that are allowed

but that should not affect other applications and users.

Priority 0 Typically used for best-effort traffic.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields.

Table 16 Basic Setting > Switch Setup (continued)

LABEL DESCRIPTION

Chapter 8 Basic Setting

GS2220 Series User’s Guide

Figure 69 Basic Setting > IP Setup

The following table describes the labels in this screen.

Table 17 Basic Setting > IP Setup

LABEL DESCRIPTION

Default Management IP Address

DHCP Client Select this option if you have a DHCP server that can assign the Switch an IP address,

subnet mask, a default gateway IP address and a domain name server IP address

automatically.

Option-60 DHCP Option 60 is used by the Switch for identification to the DHCP server using the VCI

(Vendor Class Identifier) on the DHCP server. The Switch adds it in the initial DHCP discovery

message that a DHCP client broadcasts in search of an IP address. The DHCP server can

assign different IP addresses or options to clients with the specific VCI or reject the request

from clients without the specific VCI.

Select this and enter the device identity you want the Switch to add in the DHCP discovery

frames that go to the DHCP server. This allows the Switch to identify itself to the DHCP server.

Class-ID Type a string of up to 32 characters to identify this Switch to the DHCP server. For example,

Zyxel-TW.

Static IP Address Select this option if you don’t have a DHCP server or if you wish to assign static IP address

information to the Switch. You need to fill in the following fields when you select this option.

IP Address Enter the IP address of your Switch in dotted decimal notation for example 192.168.1.1.

IP Subnet Mask Enter the IP subnet mask of your Switch in dotted decimal notation for example

255.255.255.0.

Default Gateway Enter the IP address of the default outgoing gateway in dotted decimal notation, for

example 192.168.1.254.

Chapter 8 Basic Setting

GS2220 Series User’s Guide

8.7 Port Setup

Use this screen to configure Switch port settings. Click Basic Setting > Port Setup in the navigation panel

to display the configuration screen.

VID Enter the VLAN identification number associated with the Switch IP address. This is the VLAN

ID of the CPU and is used for management only. The default is "1". All ports, by default, are

fixed members of this "management VLAN" in order to manage the device from any port. If

a port is not a member of this VLAN, then users on that port cannot access the device. To

access the Switch make sure the port that you are connected to is a member of

Management VLAN.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to your previous configuration.

Management IP Addresses

You can create up to 64 IP addresses, which are used to access and manage the Switch from the ports belonging

to the pre-defined VLAN(s). You must configure a VLAN first.

IP Address Enter the IP address for managing the Switch by the members of the VLAN specified in the

VID field below.

IP Subnet Mask Enter the IP subnet mask in dotted decimal notation.

VID Type the VLAN group identification number.

Default Gateway Enter the IP address of the default outgoing gateway in dotted decimal notation.

Add Click Add to insert the entry to the summary table below and save your changes to the

Switch’s run-time memory. The Switch loses these changes if it is turned off or loses power, so

use the Save link on the top navigation panel to save your changes to the non-volatile

memory when you are done configuring.

Cancel Click Cancel to reset the fields to your previous configuration.

Index This field displays the index number of the rule. Click an index number to edit the rule.

IP Address This field displays the IP address.

IP Subnet Mask This field displays the subnet mask.

VID This field displays the ID number of the VLAN group.

Default Gateway This field displays the IP address of the default gateway.

Delete Check the management IP addresses that you want to remove in the Delete column, then

click the Delete button.

Cancel Click Cancel to clear the selected check boxes in the Delete column.

Table 17 Basic Setting > IP Setup (continued)

LABEL DESCRIPTION

Chapter 8 Basic Setting

GS2220 Series User’s Guide

Figure 70 Basic Setting > Port Setup

The following table describes the labels in this screen.

Table 18 Basic Setting > Port Setup

LABEL DESCRIPTION

Port This is the port index number. * means all ports.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select this check box to enable a port. The factory default for all ports is enabled. A port must be

enabled for data transmission to occur.

Name Enter a descriptive name that identifies this port. You can enter up to 64 alpha-numerical

characters.

Note: Due to space limitation, the port name may be truncated in some web

configurator screens.

Type This field displays the capacity that the port can support.

Speed/Duplex Select the speed and the duplex mode of the Ethernet connection on this port. The choices are:

•10M/Half Duplex, 100M/Half Duplex, 10M/Full Duplex and 100M/Full Duplex for a 100Base-T

connection

•1G/Full Duplex for 1000Base-T and 1000Base-X connections

Selecting Auto (auto-negotiation) allows one port to negotiate with a peer port automatically

to obtain the connection speed (of up to 1000M) and duplex mode that both ends support.

When auto-negotiation is turned on, a port on the Switch negotiates with the peer

automatically to determine the connection speed and duplex mode. If the peer port does

not support auto-negotiation or turns off this feature, the Switch determines the connection

speed by detecting the signal on the cable and using half duplex mode. When the Switch’s

auto-negotiation is turned off, a port uses the pre-configured speed and duplex mode when

making a connection, thus requiring you to make sure that the settings of the peer port are

the same in order to connect.

Chapter 8 Basic Setting

GS2220 Series User’s Guide

8.8 PoE Setup

Note: The following screens are available for the PoE model(s) only.

A powered device (PD) is a device such as an access point or a switch, that supports PoE (Power over

Ethernet) so that it can receive power from another device through an Ethernet port.

In the figure below, the IP camera and IP phone get their power directly from the Switch. Aside from

minimizing the need for cables and wires, PoE removes the hassle of trying to find a nearby electric

outlet to power up devices.

Figure 71 Powered Device Examples

You can also set priorities so that the Switch is able to reserve and allocate power to certain PDs.

Note: The PoE (Power over Ethernet) devices that supply or receive power and their

connected Ethernet cables must all be completely indoors.

To view the current amount of power that PDs are receiving from the Switch, click Basic Setting > PoE

Setup.

Flow Control A concentration of traffic on a port decreases port bandwidth and overflows buffer memory

causing packet discards and frame losses. Flow Control is used to regulate transmission of signals

to match the bandwidth of the receiving port.

The Switch uses IEEE802.3x flow control in full duplex mode and backpressure flow control in half

duplex mode.

IEEE802.3x flow control is used in full duplex mode to send a pause signal to the sending port,

causing it to temporarily stop sending signals when the receiving port memory buffers fill.

Back Pressure flow control is typically used in half duplex mode to send a "collision" signal to the

sending port (mimicking a state of packet collision) causing the sending port to temporarily stop

sending signals and resend later. Select Flow Control to enable it.

802.1p Priority This priority value is added to incoming frames without a (802.1p) priority queue tag. See Priority

Queue Assignment in Table 16 on page 85 for more information.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 18 Basic Setting > Port Setup (continued)

LABEL DESCRIPTION

Chapter 8 Basic Setting

GS2220 Series User’s Guide

Figure 72 Basic Setting > PoE Setup

The following table describes the labels in this screen.

Table 19 Basic Setting > PoE Setup

LABEL DESCRIPTION

PoE Status

PoE Mode This field displays the power management mode used by the Switch, whether it is in

Classification or Consumption mode.

Total Power (W) This field displays the total power the Switch can provide to the connected PoE-enabled

devices on the PoE ports.

PoE Usage (%) This field displays the amount of power currently being supplied to connected PoE devices (PDs)

as a percentage of the total PoE power the Switch can supply.

When PoE usage reaches 100%, the Switch will shut down PDs one-by-one according to the PD

priority which you configured in Basic Setting > PoE Setup.

PoE Usage

Threshold (%)

This field displays the percentage of PoE usage. The Switch will generate a trap and/or a log

when the usage exceeds the specified threshold.

Consuming

Power (W)

This field displays the amount of power the Switch is currently supplying to the connected PoE-

enabled devices.

Allocated Power

(W)

This field displays the total amount of power the Switch has reserved for PoE after negotiating

with the connected PoE device(s).

Consuming Power (W) can be less than or equal but not more than the Allocated Power (W).

Remaining

Power (W)

This field displays the amount of power the Switch can still provide for PoE.

Port This is the port index number.

State This field shows which ports can receive power from the Switch. You can set this in Section 8.8.2

on page 93.

•Disable - The PD connected to this port cannot get power supply.

•Enable - The PD connected to this port can receive power.

Chapter 8 Basic Setting

GS2220 Series User’s Guide

8.8.1 PoE Time Range Setup

Use this screen to apply a schedule to the port(s) on the Switch. You must first configure a schedule in

the Advanced Application > Time Range screen.

Click the PoE Time Range Setup link in the Basic Setting > PoE Setup screen. The following screen opens.

Class This shows the power classification of the PD. Each PD has a specified maximum power that fall

under one of the classes.

The Class is a number from 0 to 4, where each value represents the range of power that the

Switch provides to the PD. The power ranges in PoE standards are as follows.

•Class 0 - default: 0.44 W to 15.4 W.

•Class 1 - default: 0.44 W to 4 W.

•Class 2 - default: 0.44 W to 7 W.

•Class 3 - default: 0.44 W to 15.4 W.

•Class 4 - default: 0.44 W to 30 W.

Note: You can set a limit on the maximum power the connected PD can use on a

port in Basic Setting > PoE Setup > PoE Setup.

PD Priority When the total power requested by the PDs exceeds the total PoE power budget on the Switch,

you can set the PD priority to allow the Switch to provide power to ports with higher priority first.

•Critical has the highest priority.

•High has the Switch assign power to the port after all critical priority ports are served.

•Low has the Switch assign power to the port after all critical and high priority ports are

served.

Power-Up This field displays the PoE standard the Switch uses to provide power on this port.

Consuming

Power (W)

This field displays the current amount of power consumed by the PD from the Switch on this port.

Max Power (W) This field displays the maximum amount of power the PD could use from the Switch on this port.

Time Range

State

This field shows whether or not the port currently receives power from the Switch according to its

schedule.

• It shows “In” followed by the time range name if PoE is currently enabled on the port.

• It shows “Out” if PoE is currently disabled on the port.

• It shows “-” if no schedule is applied to the port. PoE is enabled by default.

Table 19 Basic Setting > PoE Setup (continued)

LABEL DESCRIPTION

Chapter 8 Basic Setting

GS2220 Series User’s Guide

Figure 73 Basic Setting > PoE Setup > PoE Time Range Setup

The following table describes the labels in this screen.

8.8.2 PoE Se tup

Use this screen to set the PoE power management mode, priority levels, power-up mode and the

maximum amount of power for the connected PDs.

Click the PoE Setup link in the Basic Setting > PoE Setup screen. The following screen opens.

Table 20 Basic Setting > PoE Setup > PoE Time Range Setup

LABEL DESCRIPTION

Port Time Range Setup

Port Enter the port number you want to configure.

Time

Range Select one or more time range profiles that determine when PoE will be enabled in this port. You

can configure time range profiles in Advanced Application > Time Range.

You can select multiple profiles by holding the Ctrl key before clicking on multiple profiles, or by

clicking on one profile and dragging your mouse to select the desired profiles.

Note: The schedules you assign to one port must not have any overlap.

Apply Click this button to apply the selected time range profile(s) on the specified port.

Cancel Click this button to reset the Port and Time Range fields.

Port This is the number of the port on the Switch. Click this number to configure the PoE time range of

this port.

Time Range

Profiles

This field displays the name of the schedule(s) applied to the port. If a schedule is assigned to a

port, PoE is enabled only at the time/date specified in the time range profile(s). If no schedule is

assigned, PoE is enabled by default.

Click a check box to select a corresponding port. Select the topmost check box to select all

ports.

Delete Click this button to delete the time range profile of the selected port(s).

Cancel Click this button to clear all check boxes.

Chapter 8 Basic Setting

GS2220 Series User’s Guide

Figure 74 Basic Setting > PoE Setup > PoE Setup

The following table describes the labels in this screen.

Table 21 Basic Setting > PoE Setup

LABEL DESCRIPTION

PoE Mode Select the power management mode you want the Switch to use.

•Classification - Select this if you want the Switch to reserve the maximum power for each PD

according to the PD’s power class and priority level. If the total power supply runs out, PDs

with lower priority do not get power to function. In this mode, the maximum power is reserved

based on what you configure in Max Power or the standard power limit for each class.

•Consumption - Select this if you want the Switch to supply the actual power that the PD

needs. The Switch also allocates power based on a port’s M ax Power and the PD’s power

class and priority level. The Switch puts a limit on the maximum amount of power the PD can

request and use. In this mode, the default maximum power that can be delivered to the PD is

33 W (IEEE 802.3at Class 4) or 22 W (IEEE 802.3af Classes 0 to 3).

PoE Usage

Threshold (%)

Enter a number ranging from 1 to 99 to set the threshold. The Switch will generate a trap and/or

log when the actual PoE usage is higher than the specified threshold.

Port This is the port index number.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

PD Select this to provide power to a PD connected to the port.

If left unchecked, the PD connected to the port cannot receive power from the Switch.

PD Priority When the total power requested by the PDs exceeds the total PoE power budget on the Switch,

you can set the PD priority to allow the Switch to provide power to ports with higher priority.

Select Critical to give the highest PD priority on the port.

Select High to set the Switch to assign the remaining power to the port after all critical priority

ports are served.

Select Low to set the Switch to assign the remaining power to the port after all critical and high

priority ports are served.

Chapter 8 Basic Setting

GS2220 Series User’s Guide

Power-Up Set how the Switch provides power to a connected PD at power-up.

802.3af - the Switch follows the IEEE 802.3af Power over Ethernet standard to supply power to the

connected PDs during power-up.

Legacy - the Switch can provide power to the connected PDs that require high inrush currents at

power-up. Inrush current is the maximum, instantaneous input current drawn by the PD when first

turned on.

Pre-802.3at - the Switch initially offers power on the port according to the IEEE 802.3af standard,

and then switches to support the IEEE 802.3at standard within 75 milliseconds after a PD is

connected to the port. Select this option if the Switch is performing 2-event Layer-1 classification

(PoE+ hardware classification) or the connected PD is NOT performing Layer 2 power

classification using Link Layer Discovery Protocol (LLDP).

802.3at - the Switch supports the IEEE 802.3at High Power over Ethernet standard and can supply

power of up to 30W per Ethernet port. IEEE 802.3at is also known as PoE+ or PoE Plus. An IEEE

802.3at compatible device is referred to as Type 2. Power Class 4 (High Power) can only be used

by Type 2 devices. If the connected PD requires a Class 4 current when it is turned on, it will be

powered up in this mode.

Force-802.3at - the Switch offers power of up to 33W on the port without performing PoE

hardware classification. Select this option if the connected PD doesn’t comply with any PoE

standard and requests power higher than a standard power limit.

Max Power

(mW)

Specify the maximum amount of power the PD could use from the Switch on this port. If you leave

this field blank, the Switch refers to the standard or default maximum power for each class.

Wide Range

Detection

Select this to let the Switch have a wider detection range for the PD.

The Switch detects whether a connected device is a powered device or not before supplying

power to the port. For the PD detection, the Switch applies a fixed voltage to the device and

then receives returned current. If the returned current is within the IEEE 802.3AF/AT standard

range, the device will be considered as a valid PD by the Switch.

However, in real cases, environmental interferences might easily cause the returned current to be

out of the standard range.

LLDP Power Via

MDI

Select this to have the Switch negotiate PoE power with the PD connected to the port by

transmitting LLDP Power Via MDI TLV frames. This helps the Switch allocate less power to the PD on

this port. The connected PD must be able to request PoE power through LLDP.

The Power Via MDI TLV allows PoE devices to advertise and discover the MDI power support

capabilities of the sending port on the remote device.

• Port Class

• MDI Supported

•MDI Enabled

• Pair Controllable

• PSE Power Pairs

•Power Class

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 21 Basic Setting > PoE Setup (continued)

LABEL DESCRIPTION

Chapter 8 Basic Setting

GS2220 Series User’s Guide

8.9 Interface Setup

An IPv6 address is configured on a per-interface basis. The interface can be a physical interface (for

example, an Ethernet port) or a virtual interface (for example, a VLAN). The Switch supports the VLAN

interface type for IPv6 at the time of writing.

Use this screen to set IPv6 interfaces on which you can configure an IPv6 address to access and

manage the Switch. Click Basic Setting > Interface Setup in the navigation panel to display the

configuration screen.

Figure 75 Basic Setting > Interface Setup

The following table describes the labels in this screen.

Table 22 Basic Setting > Interface Setup

LABEL DESCRIPTION

Interface Type Select the type of IPv6 interface for which you want to configure. The Switch supports the VLAN

interface type for IPv6 at the time of writing.

Interface ID Specify a unique identification number (from 1 to 4094) for the interface.

To have IPv6 function properly, you should configure a static VLAN with the same ID number in the

Advanced Application > VLAN screens.

Add Click this to create a new entry.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your changes

to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to your previous configuration.

Index This field displays the index number of an entry.

Interface Type This field displays the type of interface.

Interface ID This field displays the identification number of the interface.

Interface This field displays the interface’s descriptive name which is generated automatically by the

Switch. The name is from a combination of the interface type and ID number.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Click Delete to remove the selected entry from the summary table.

Cancel Click Cancel to clear the check boxes.

Chapter 8 Basic Setting

GS2220 Series User’s Guide

8.10 IPv6

Use this screen to view the IPv6 interface status and configure Switch’s management IPv6 addresses.

Click Basic Setting > IPv6 in the navigation panel to display the IPv6 status screen as shown next.

Figure 76 Basic Setting > IPv6

The following table describes the labels in this screen.

8.10.1 IPv6 Interface Status

Use this screen to view a specific IPv6 interface status and detailed information. Click an interface index

number in the Basic Setting > IPv6 screen. The following screen opens.

Table 23 Basic Setting > IPv6

LABEL DESCRIPTION

Index This field displays the index number of an IPv6 interface. Click on an index number to view more

interface details.

Interface This is the name of the IPv6 interface you created.

Active This field displays whether the IPv6 interface is activated or not.

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Figure 77 Basic Setting > IPv6 > IPv6 Interface Status

The following table describes the labels in this screen.

Table 24 Basic Setting > IPv6 > IPv6 Interface Status

LABEL DESCRIPTION

IPv6 Active This field displays whether the IPv6 interface is activated or not.

MTU Size This field displays the Maximum Transmission Unit (MTU) size for IPv6 packets on this

interface.

ICMPv6 Rate Limit Bucket

Size

This field displays the maximum number of ICMPv6 error messages which are

allowed to transmit in a given time interval. If the bucket is full, subsequent error

messages are suppressed.

ICMPv6 Rate Limit Error

Interval

This field displays the time period (in milliseconds) during which ICMPv6 error

messages of up to the bucket size can be transmitted. 0 means no limit.

Stateless Address

Autoconfig

This field displays whether the Switch’s interface can automatically generate a link-

local address via stateless autoconfiguration.

Link Local Address This field displays the Switch’s link-local IP address and prefix generated by the

interface. It also shows whether the IP address is preferred, which means it is a valid

address and can be used as a sender or receiver address.

Global Unicast Address(es) This field displays the Switch’s global unicast address to identify this interface.

Joined Group Address(es) This field displays the IPv6 multicast addresses of groups the Switch’s interface joins.

ND DAD Active This field displays whether Neighbor Discovery (ND) Duplicate Address Detection

(DAD) is enabled on the interface.

Number of DAD Attempts This field displays the number of consecutive neighbor solicitations the Switch sends

for this interface.

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8.10.2 IPv6 Configuration

Use this screen to configure IPv6 settings on the Switch. Click the IPv6 Configuration link in the Basic

Setting > IPv6 screen. The following screen opens.

NS-Interval (millisecond) This field displays the time interval (in milliseconds) at which neighbor solicitations are

re-sent for this interface.

ND Reachable Time

(millisecond)

This field displays how long (in milliseconds) a neighbor is considered reachable for

this interface.

DHCPv6 Client Active This field displays whether the Switch acts as a DHCPv6 client to get an IPv6 address

from a DHCPv6 server.

Identity Association An Identity Association (IA) is a collection of addresses assigned to a DHCP client,

through which the server and client can manage a set of related IP addresses. Each

IA must be associated with exactly one interface.

IA Type The IA type is the type of address in the IA. Each IA holds one type of address. IA_NA

means an identity association for non-temporary addresses and IA_TA is an identity

association for temporary addresses.

IAID Each IA consists of a unique IAID and associated IP information.

T1 This field displays the DHCPv6 T1 timer. After T1, the Switch sends the DHCPv6 server a

Renew message.

An IA_NA option contains the T1 and T2 fields, but an IA_TA option does not. The

DHCPv6 server uses T1 and T2 to control the time at which the client contacts with

the server to extend the lifetimes on any addresses in the IA_NA before the lifetimes

expire.

T2 This field displays the DHCPv6 T2 timer. If the time T2 is reached and the server does

not respond, the Switch sends a Rebind message to any available server.

State This field displays the state of the TA. It shows

Active when the Switch obtains addresses from a DHCpv6 server and the TA is

created.

Renew when the TA’s address lifetime expires and the Switch sends out a Renew

message.

Rebind when the Switch doesn’t receive a response from the original DHCPv6 server

and sends out a Rebind message to another DHCPv6 server

SID This field displays the DHCPv6 server’s unique ID.

Address This field displays the Switch’s global address which is assigned by the DHCPv6

server.

Preferred Lifetime This field displays how long (in seconds) that the global address remains preferred.

Valid Lifetime This field displays how long (in seconds) that the global address is valid.

DNS This field displays the DNS server address assigned by the DHCPv6 server.

Domain List This field displays the address record when the Switch queries the DNS server to

resolve domain names.

Restart DHCPv6 Client Click Click Here to send a new DHCP request to the DHCPv6 server and update the

IPv6 address and DNS information for this interface.

Table 24 Basic Setting > IPv6 > IPv6 Interface Status

LABEL DESCRIPTION

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Figure 78 Basic Setting > IPv6 > IPv6 Configuration

The following table describes the labels in this screen.

8.10.3 IPv6 Global Setup

Use this screen to configure the global IPv6 settings. Click the link next to IPv6 Global Setup in the IPv6

Configuration screen to display the screen as shown next.

Figure 79 Basic Setting > IPv6 > IPv6 Configuration > IPv6 Global Setup

Table 25 Basic Setting > IPv6 > IPv6 Configuration

LABEL DESCRIPTION

IPv6 Global

Setup

Click the link to go to a screen where you can configure the global IPv6 settings on the Switch.

IPv6 Interface

Setup

Click the link to go to a screen where you can enable an IPv6 interface on the Switch.

IPv6 Addressing

IPv6 Link-

Local

Address

Setup

Click the link to go to a screen where you can configure the IPv6 link-local address for an

interface.

IPv6 Global

Address

Setup

Click the link to go to a screen where you can configure the IPv6 global address for an interface.

IPv6 Neighbor Discovery

IPv6

Neighbor

Discovery

Setup

Click the link to go to a screen where you can configure the IPv6 neighbor discovery settings.

IPv6 Neighbor

Setup

Click the link to go to a screen where you can create a static IPv6 neighbor entry in the Switch’s

IPv6 neighbor table.

DHCPv6 Client

Setup

Click the link to go to a screen where you can configure the Switch DHCP settings.

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The following table describes the labels in this screen.

8.10.4 IPv6 Interface Setup

Use this screen to turn on or off an IPv6 interface and enable stateless auto-configuration on it. Click the

link next to IPv6 Interface Setup in the IPv6 Configuration screen to display the screen as shown next.

Figure 80 Basic Setting > IPv6 > IPv6 Configuration > IPv6 Interface Setup

The following table describes the labels in this screen.

Table 26 Basic Setting > IPv6 > IPv6 Configuration > IPv6 Global Setup

LABEL DESCRIPTION

IPv6 Hop Limit Specify the maximum number of hops (from 1 to 255) in router advertisements. This is the

maximum number of hops on which an IPv6 packet is allowed to transmit before it is discarded by

an IPv6 router, which is similar to the TTL field in IPv4.

ICMPv6 Rate

Limit Bucket

Size

Specify the maximum number of ICMPv6 error messages (from 1 to 200) which are allowed to

transmit in a given time interval. If the bucket is full, subsequent error messages are suppressed.

ICMPv6 Rate

Limit Error

Interval

Specify the time period (from 0 to 2147483647 milliseconds) during which ICMPv6 error messages

of up to the bucket size can be transmitted. 0 means no limit.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the nonvolatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Clear Click Clear to reset the fields to the factory defaults.

Table 27 Basic Setting > IPv6 > IPv6 Configuration > IPv6 Interface Setup

LABEL DESCRIPTION

Interface Select the IPv6 interface you want to configure.

Active Select this option to enable the interface.

Address

Autoconfig

Select this option to allow the interface to automatically generate a link-local address via

stateless autoconfiguration.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the nonvolatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Clear Click Clear to reset the fields to the factory defaults.

Index This is the interface index number. Click on an index number to change the settings.

Interface This is the name of the IPv6 interface you created.

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8.10.5 IPv6 Link-Local Address Setup

A link-local address uniquely identifies a device on the local network (the LAN). It is similar to a “private IP

address” in IPv4. You can have the same link-local address on multiple interfaces on a device. A link-

local unicast address has a predefined prefix of fe80::/10.

Use this screen to configure the interface’s link-local address and default gateway. Click the link next to

IPv6 Link-Local Address Setup in the IPv6 Configuration screen to display the screen as shown next.

Figure 81 Basic Setting > IPv6 > IPv6 Configuration > IPv6 Link-Local Address Setup

The following table describes the labels in this screen.

Active This field displays whether the IPv6 interface is activated or not.

Address

Autoconfig

This field displays whether stateless autoconfiguration is enabled on the interface.

Table 27 Basic Setting > IPv6 > IPv6 Configuration > IPv6 Interface Setup (continued)

LABEL DESCRIPTION

Table 28 Basic Setting > IPv6 > IPv6 Configuration > IPv6 Link-Local Address Setup

LABEL DESCRIPTION

Interface Select the IPv6 interface you want to configure.

Link-Local

Address

Manually configure a static IPv6 link-local address for the interface.

Default

Gateway

Set the default gateway IPv6 address for the interface. When an interface cannot find a routing

information for a frame’s destination, it forwards the packet to the default gateway.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the nonvolatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Clear Click Clear to reset the fields to the factory defaults.

Index This is the interface index number. Click on an index number to change the settings.

Interface This is the name of the IPv6 interface you created.

IPv6 Link-Local

Address

This is the static IPv6 link-local address for the interface.

IPv6 Default

Gateway

This is the default gateway IPv6 address for the interface.

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8.10.6 IPv6 Global Address Setup

Use this screen to configure the interface’s IPv6 global address. Click the link next to IPv6 Global Address

Setup in the IPv6 Configuration screen to display the screen as shown next.

Figure 82 Basic Setting > IPv6 > IPv6 Configuration > IPv6 Global Address Setup

The following table describes the labels in this screen.

8.10.7 IPv6 Neighbor Discovery Setup

Use this screen to configure neighbor discovery settings for each interface. Click the link next to IPv6

Neighbor Discovery Setup in the IPv6 Configuration screen to display the screen as shown next.

Table 29 Basic Setting > IPv6 > IPv6 Configuration > IPv6 Global Address Setup

LABEL DESCRIPTION

Interface Select the IPv6 interface you want to configure.

IPv6 Global

Address

Manually configure a static IPv6 global address for the interface.

Prefix Length Specify an IPv6 prefix length that specifies how many most significant bits (start from the left) in

the address compose the network address.

EUI-64 Select this option to have the interface ID be generated automatically using the EUI-64 format.

Add Click Add to save your changes to the Switch’s run-time memory. The Switch loses these changes

if it is turned off or loses power, so use the Save link on the top navigation panel to save your

changes to the nonvolatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Clear Click Clear to reset the fields to the factory defaults.

Index This is the interface index number. Click on an index number to change the settings.

Interface This is the name of the IPv6 interface you created.

IPv6 Global

Address/Prefix

Length

This field displays the IPv6 global address and prefix length for the interface.

EUI-64 This shows whether the interface ID of the global address is generated using the EUI-64 format.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Check the entry(ies) that you want to remove and then click Delete to remove the selected

entry(ies) from the summary table.

Cancel Click Cancel to clear the check boxes.

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Figure 83 Basic Setting > IPv6 > IPv6 Configuration > IPv6 Neighbor Discovery Setup

The following table describes the labels in this screen.

8.10.8 IPv6 Neighbor Setup

Use this screen to create a static IPv6 neighbor entry in the Switch’s IPv6 neighbor table to store the

neighbor information permanently. Click the link next to IPv6 Neighbor Setup in the IPv6 Configuration

screen to display the screen as shown next.

Table 30 Basic Setting > IPv6 > IPv6 Configuration > IPv6 Neighbor Discovery Setup

LABEL DESCRIPTION

Interface Select the IPv6 interface you want to configure.

DAD Attempts The Switch uses Duplicate Address Detection (DAD) with neighbor solicitation and advertisement

messages to check whether an IPv6 address is already in use before assigning it to an interface,

such as the link-local address it creates through stateless address autoconfiguration.

Specify the number of consecutive neighbor solicitations (from 0 to 600) the Switch sends for this

interface. Enter 0 to turn off DAD.

NS Interval Specify the time interval (from 1000 to 3600000 milliseconds) at which neighbor solicitations are re-

sent for this interface.

Reachable

Time

Specify how long (from 1000 to 3600000 milliseconds) a neighbor is considered reachable for this

interface.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the nonvolatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Clear Click Clear to reset the fields to the factory defaults.

Index This is the interface index number. Click on an index number to change the settings.

Interface This is the name of the IPv6 interface you created.

DAD Attempts This field displays the number of consecutive neighbor solicitations the Switch sends for this

interface.

NS Interval This field displays the time interval (in milliseconds) at which neighbor solicitations are re-sent for

this interface.

Reachable

Time

This field displays how long (in milliseconds) a neighbor is considered reachable for this interface.

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Figure 84 Basic Setting > IPv6 > IPv6 Configuration > IPv6 Neighbor Setup

The following table describes the labels in this screen.

Table 31 Basic Setting > IPv6 > IPv6 Configuration > IPv6 Neighbor Setup

LABEL DESCRIPTION

Interface Type Select the type of IPv6 interface for which you want to configure. The Switch supports the VLAN

interface type for IPv6 at the time of writing.

Interface ID Specify a unique identification number (from 1 to 4094) for the interface.

A static IPv6 neighbor entry displays in the Management > Neighbor Table screen only when the

interface ID is also created in the Basic Setup > Interface Setup screen.

To have IPv6 function properly, you should configure a static VLAN with the same ID number in the

Advanced Application > VLAN screens.

Neighbor

Address

Specify the IPv6 address of the neighboring device which can be reached through the interface.

MAC Specify the MAC address of the neighboring device which can be reached through the

interface.

Add Click this to create a new entry or to update an existing one.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your changes

to the nonvolatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Clear Click Clear to reset the fields to the factory defaults.

Index This is the interface index number. Click on an index number to change the settings.

Interface This is the name of the IPv6 interface you created.

Neighbor

Address

This field displays the IPv6 address of the neighboring device which can be reached through the

interface

MAC This field displays the MAC address of the neighboring device which can be reached through the

interface.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the table

heading row to select all entries.

Delete Check the entry(ies) that you want to remove and then click Delete to remove the selected

entry(ies) from the summary table.

Cancel Click Cancel to clear the check boxes.

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8.10.9 DHCPv6 Client Setup

Use this screen to configure the Switch’s DHCP settings when it is acting as a DHCPv6 client. Click the link

next to DHCPv6 Client Setup in the IPv6 Configuration screen to display the screen as shown next.

Figure 85 Basic Setting > IPv6 > IPv6 Configuration > DHCPv6 Client Setup

The following table describes the labels in this screen.

Table 32 Basic Setting > IPv6 > IPv6 Configuration > DHCPv6 Client Setup

LABEL DESCRIPTION

Interface Select the IPv6 interface you want to configure.

IA Type Select IA-NA to set the Switch to get a non-temporary IP address from the DHCPv6 server for this

interface.

Optionally, you can also select Rapid-Commit to have the Switch send its DHCPv6 Solicit message

with a Rapid Commit option to obtain information from the DHCPv6 server by a rapid two-

message exchange. The Switch discards any Reply messages that do not include a Rapid

Commit option. The DHCPv6 server should also support the Rapid Commit option to have it work

well.

Options Select DNS to have the Switch obtain DNS server IPv6 addresses and/or select Domain-List to

have the Switch obtain a list of domain names from the DHCP server.

Information

Refresh

Minimum

Specify the time interval (from 600 to 4294967295 seconds) at which the Switch exchanges other

configuration information with a DHCPv6 server again.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the nonvolatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Clear Click Clear to reset the fields to the factory defaults.

Index This is the interface index number. Click on an index number to change the settings.

Interface This is the name of the IPv6 interface you created.

IA-NA This field displays whether the Switch obtains a non-temporary IP address from the DHCPv6 server.

Rapid-Commit This field displays whether the Switch obtains information from the DHCPv6 server by a rapid two-

message exchange.

DNS This field displays whether the Switch obtains DNS server IPv6 addresses from the DHCPv6 server.

Domain-List This field displays whether the Switch obtains a list of domain names from the DHCP server.

Information

Refresh

Minimum

This field displays the time interval (in seconds) at which the Switch exchanges other configuration

information with a DHCPv6 server again.

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8.11 DNS

DNS (Domain Name System) is for mapping a domain name to its corresponding IP address and vice

versa. Use the DNS screen to configure and view the default DNS servers on the Switch.

Figure 86 Basic Setting > DNS

The following table describes the labels in this screen.

8.12 Cloud Management

The Zyxel Nebula Control Center (NCC) is a cloud-based network management system that allows you

to remotely manage and monitor Zyxel Nebula APs, Ethernet switches and security gateways.

The Switch is managed and provisioned automatically by the NCC (Nebula Control Center) when:

• It is connected to the Internet

• The Nebula Control Center Discovery feature is enabled

• It has been registered in the NCC.

Table 33 Basic Setting > DNS

LABEL DESCRIPTION

Static Domain Name Server

Preference This is the priority of the DNS server address.

Server Address Enter a domain name server IPv6/IPv4 address in order to be able to use a domain name

instead of an IP address.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the nonvolatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to your previous configuration.

Domain Name Server Table

Index This field displays priority of the DNS server address.

Server Address This field displays the IP address of the DNS server.

Source This field displays whether the DNS server address is configured manually (Static) or

obtained automatically using DHCPv4 or DHCPv6.

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This screen displays links to Nebula Control Center Discovery where you can have the Switch search for

the NCC (Nebula Control Center) and to Nebula Switch Registration which has a QR code containing

the Switch’s serial number and MAC address for handy registration of the Switch at NCC.

Click Basic Setting > Cloud Management in the navigation panel to display this screen.

Figure 87 Basic Setting > Cloud Management

8.12.1 Nebula Control Center Discovery

Click Basic Setting > Cloud Management > Nebula Control Center Discovery to display this screen.

Figure 88 Basic Setting > Cloud Management > Nebula Control Center Discovery

Select Active to turn on NCC discovery on the Switch. If the Switch has Internet access and has been

registered in the NCC, it will go into cloud management mode.

In cloud management mode, then NCC will first check if the firmware on the Switch needs to be

upgraded. If it does, the Switch will upgrade the firmware immediately. If the firmware doesn’t need to

be upgraded, but there is newer firmware available for the Switch, then it will be upgraded according

to the firmware upgrade schedule for the Switch on the NCC. Below is the process for upgrading

firmware:

1Download firmware via the NCC

2Upgrade the firmware and reboot.

Note: While the Switch is rebooting, don’t turn off the power.

Clear Active to turn off NCC discovery on the Switch. The Switch will not discover the NCC and remain in

standalone mode. See Section 1.1.2 on page 22 for more information.

8.12.2 Nebula Switch Registration

Click Basic Setting > Cloud Management > Nebula Switch Registration to display this screen.

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Figure 89 Basic Setting > Cloud Management > Nebula Switch Registration

This screen has a QR code containing the Switch’s serial number and MAC address for handy NCC

registration of the Switch using the Nebula Mobile app. First, download the app from the Google Play

store for Android devices or the App Store for iOS devices and create an organization and site.

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CHAPTER 9

VLAN

9.1 Overview

This chapter shows you how to configure 802.1Q tagged and port-based VLANs. The type of screen you

see here depends on the VLAN Type you selected in the Switch Setup screen.

Note: If you've enabled CLV mode in the Command Line Interface (CLI) to configure the

Switch's VLAN settings, further VLAN changes you make via the web configurator will

not be saved and applied completely. You can still use the web configurator to view

the VLAN status.

If you want to configure VLAN settings in both the web configurator and the CLI, just

return to Zyxel configuration mode by turning off CLV mode. See the CLI Reference

Guide for more information about CLV mode.

9.1.1 What You Can Do

• Use the VLAN Status screen (Section 9.2 on page 114) to view and search all VLAN groups.

• Use the VLAN Detail screen (Section 9.2.1 on page 115) to view detailed port settings and status of the

VLAN group.

• Use the Static VLAN Setup screen (Section 9.4 on page 116) to configure and view 802.1Q VLAN

parameters for the Switch.

• Use the VLAN Port Setup screen (Section 9.5 on page 118) to configure the static VLAN (IEEE 802.1Q)

settings on a port.

• Use the Subnet Based VLAN Setup screen (Section 9.6 on page 119) to set up VLANs that allow you to

group traffic into logical VLANs based on the source IP subnet you specify.

• Use the Protocol Based VLAN Setup screen (Section 9.7 on page 121) to set up VLANs that allow you

to group traffic into logical VLANs based on the protocol you specify.

• Use the Voice VLAN Setup screen (Section 9.8 on page 123) to set up VLANs that allow you to group

voice traffic with defined priority and enable the switch port to carry the voice traffic separately from

data traffic to ensure the sound quality does not deteriorate.

• Use the MAC Based VLAN Setup screen (Section 9.9 on page 125) to set up VLANs that allow you to

group untagged packets into logical VLANs based on the source MAC address of the packet. This

eliminates the need to reconfigure the switch when you change ports. The switch will forward the

packets based on the source MAC address you setup previously.

• Use the Vendor ID Based VLAN Setup screen (Section 9.10 on page 126) to set up VLANs that allow

you to group untagged packets into logical VLANs based on the source MAC address of the packet.

You can specify a mask for the MAC address to create a MAC address filter and enter a weight to set

the VLAN rule’s priority.

• Use the Port-Based VLAN screen (Section 9.11 on page 128) to set up VLANs where the packet

forwarding decision is based on the destination MAC address and its associated port.

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9.1.2 What You Need to Know

Read this section to know more about VLAN and how to configure the screens.

IEEE 802.1Q Tagged VLANs

A tagged VLAN uses an explicit tag (VLAN ID) in the MAC header to identify the VLAN membership of a

frame across bridges - they are not confined to the switch on which they were created. The VLANs can

be created statically by hand or dynamically through GVRP. The VLAN ID associates a frame with a

specific VLAN and provides the information that switches need to process the frame across the network.

A tagged frame is four bytes longer than an untagged frame and contains two bytes of TPID (Tag

Protocol Identifier, residing within the type/length field of the Ethernet frame) and two bytes of TCI (Tag

Control Information, starts after the source address field of the Ethernet frame).

The CFI (Canonical Format Indicator) is a single-bit flag, always set to zero for Ethernet switches. If a

frame received at an Ethernet port has a CFI set to 1, then that frame should not be forwarded as it is to

an untagged port. The remaining twelve bits define the VLAN ID, giving a possible maximum number of

4,096 VLANs. Note that user priority and VLAN ID are independent of each other. A frame with VID

(VLAN Identifier) of null (0) is called a priority frame, meaning that only the priority level is significant and

the default VID of the ingress port is given as the VID of the frame. Of the 4096 possible VIDs, a VID of 0 is

used to identify priority frames and value 4095 (FFF) is reserved, so the maximum possible VLAN

configurations are 4,094.

Forwarding Tagged and Untagged Frames

Each port on the Switch is capable of passing tagged or untagged frames. To forward a frame from an

802.1Q VLAN-aware switch to an 802.1Q VLAN-unaware switch, the Switch first decides where to

forward the frame and then strips off the VLAN tag. To forward a frame from an 802.1Q VLAN-unaware

switch to an 802.1Q VLAN-aware switch, the Switch first decides where to forward the frame, and then

inserts a VLAN tag reflecting the ingress port's default VID. The default PVID is VLAN 1 for all ports, but this

can be changed.

A broadcast frame (or a multicast frame for a multicast group that is known by the system) is duplicated

only on ports that are members of the VID (except the ingress port itself), thus confining the broadcast to

a specific domain.

9.1.2.1 Automatic VLAN Registration

GARP and GVRP are the protocols used to automatically register VLAN membership across switches.

GARP

GARP (Generic Attribute Registration Protocol) allows network switches to register and de-register

attribute values with other GARP participants within a bridged LAN. GARP is a protocol that provides a

generic mechanism for protocols that serve a more specific application, for example, GVRP.

TPID

2 Bytes

User Priority

3 Bits

CFI

1 Bit

VLAN ID

12 bits

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GARP Timers

Switches join VLANs by making a declaration. A declaration is made by issuing a Join message using

GARP. Declarations are withdrawn by issuing a Leave message. A Leave All message terminates all

registrations. GARP timers set declaration timeout values.

GVRP

GVRP (GARP VLAN Registration Protocol) is a registration protocol that defines a way for switches to

groups beyond the local Switch.

Please refer to the following table for common IEEE 802.1Q VLAN terminology.

9.1.2.2 Port VLAN Trunking

Enable VLAN Trunking on a port to allow frames belonging to unknown VLAN groups to pass through

that port. This is useful if you want to set up VLAN groups on end devices without having to configure the

same VLAN groups on intermediary devices.

Refer to the following figure. Suppose you want to create VLAN groups 1 and 2 (V1 and V2) on devices

A and B. Without VLAN Trunking, you must configure VLAN groups 1 and 2 on all intermediary switches C,

D and E; otherwise they will drop frames with unknown VLAN group tags. However, with VLAN Trunking

enabled on a port(s) in each intermediary switch you only need to create VLAN groups in the end

devices (A and B). C, D and E automatically allow frames with VLAN group tags 1 and 2 (VLAN groups

that are unknown to those switches) to pass through their VLAN trunking port(s).

Table 34 IEEE 802.1Q VLAN Terminology

VLAN PARAMETER TERM DESCRIPTION

VLAN Type Permanent VLAN This is a static VLAN created manually.

Dynamic VLAN This is a VLAN configured by a GVRP registration/deregistration

process.

VLAN Administrative

Control

Registration Fixed Fixed registration ports are permanent VLAN members.

Registration

Forbidden

Ports with registration forbidden are forbidden to join the specified

VLAN.

Normal Registration Ports dynamically join a VLAN using GVRP.

VLAN Tag Control Tagged Ports belonging to the specified VLAN tag all outgoing frames

transmitted.

Untagged Ports belonging to the specified VLAN don't tag all outgoing frames

transmitted.

VLAN Port Port VID This is the VLAN ID assigned to untagged frames that this port

received.

Acceptable Frame

Type

You may choose to accept both tagged and untagged incoming

frames, just tagged incoming frames or just untagged incoming

frames on a port.

Ingress filtering If set, the Switch discards incoming frames for VLANs that do not

have this port as a member

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Figure 90 Port VLAN Trunking

9.1.2.3 VLAN Priority

At the time of writing, you can create Static VLANs, Voice VLANs, Vendor ID-based VLANs, Subnet Based

VLANs, Protocol Based VLANs and MAC Based VLANs on the Switch when the VLAN type is set to 802.1Q.

When a packet is received, the Switch processes the VLAN rules in sequence. The sequence (priority) of

the VLANs is:

1Vendor ID Based VLAN

2Voice VLAN

3Subnet Based VLAN

4Protocol Based VLAN

5MAC Based VLAN

If the packet matches a VLAN rule that has a higher priority, for example, an entry with weight 250 in the

vendor ID to VLAN mapping table, the Switch assigns the corresponding VLAN ID to the packet and

stops checking the subsequent VLAN rules.

9.1.2.4 Select the VLAN Type

Select a VLAN type in the Basic Setting > Switch Setup screen.

Figure 91 Switch Setup > Select VLAN Type

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Static VLAN

Use a static VLAN to decide whether an incoming frame on a port should be

• sent to a VLAN group as normal depending on its VLAN tag.

• sent to a group whether it has a VLAN tag or not.

• blocked from a VLAN group regardless of its VLAN tag.

You can also tag all outgoing frames (that were previously untagged) from a port with the specified

VID.

9.2 VLAN Status

Use this screen to view and search all VLAN groups. Click Advanced Application > VLAN from the

navigation panel to display the VLAN Status screen as shown next.

Figure 92 Advanced Application > VLAN: VLAN Status

The following table describes the labels in this screen.

Table 35 Advanced Application > VLAN: VLAN Status

LABEL DESCRIPTION

VLAN Search by

VID

Enter an existing VLAN ID number(s) (separated by a comma) and click Search to display only

the specified VLAN(s) in the list below.

Leave this field blank and click Search to display all VLANs configured on the Switch.

The Number of

VLAN

This is the number of VLANs configured on the Switch.

The Number of

Search Results

This is the number of VLANs that match the searching criteria and display in the list below.

This field displays only when you use the Search button to look for certain VLANs.

Index This is the VLAN index number. Click on an index number to view more VLAN details.

VID This is the VLAN identification number that was configured in the Static VLAN screen.

Name This fields shows the descriptive name of the VLAN.

Tagged Port This field shows the tagged ports that are participating in the VLAN.

Untagged Port This field shows the untagged ports that are participating in the VLAN.

Elapsed Time This field shows how long it has been since a normal VLAN was registered or a static VLAN was

set up.

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9.2.1 VLAN Detail

Use this screen to view detailed port settings and status of the VLAN group. Click on an index number in

the VLAN Status screen to display VLAN details.

Figure 93 Advanced Application > VLAN > VLAN Detail

The following table describes the labels in this screen.

9.3 VLAN Configuration

Use this screen to view IEEE 802.1Q VLAN parameters for the Switch. Click Advanced Application > VLAN

> VLAN Configuration to see the following screen.

Status This field shows how this VLAN was added to the Switch.

Dynamic: using GVRP

Static: added as a permanent entry

Change Pages Click Previous or Next to show the previous/next screen if all status information cannot be seen in

one screen.

Table 35 Advanced Application > VLAN: VLAN Status (continued)

LABEL DESCRIPTION

Table 36 Advanced Application > VLAN > VLAN Detail

LABEL DESCRIPTION

VLAN Status Click this to go to the VLAN Status screen.

VID This is the VLAN identification number that was configured in the Static VLAN screen.

Port Number This column displays the ports that are participating in a VLAN. A tagged port is marked as T, an

untagged port is marked as U and ports not participating in a VLAN are marked as “–“.

Elapsed Time This field shows how long it has been since a normal VLAN was registered or a static VLAN was

set up.

Status This field shows how this VLAN was added to the Switch.

Dynamic: using GVRP

Static: added as a permanent entry

Voice: manually added as a Voice VLAN

MVR: added via multicast VLAN registration

MAC-based: manually added as MAC-based VLAN

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Figure 94 Advanced Application > VLAN > VLAN Configuration

The following table describes the labels in the above screen.

9.4 Configure a Static VLAN

Use this screen to configure a static VLAN for the Switch. Click the Static VLAN Setup link in the VLAN

Configuration screen to display the screen as shown next.

Table 37 Advanced Application > VLAN > VLAN Configuration

LABEL DESCRIPTION

Static VLAN Setup Click Click Here to configure the Static VLAN for the Switch.

VLAN Port Setup Click Click Here to configure the VLAN Port for the Switch.

Subnet Based VLAN Setup Click Click Here to configure the Subnet Based VLAN for the Switch.

Protocol Based VLAN Setup Click Click Here to configure the Protocol Based VLAN for the Switch.

Voice VLAN Setup Click Click Here to configure the Voice VLAN for the Switch.

MAC Based VLAN Setup Click Click Here to configure the MAC Based VLAN for the Switch.

Vendor ID Based VLAN

Setup

Click Click Here to configure the Vendor ID Based VLAN for the Switch.

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Figure 95 Advanced Application > VLAN > VLAN Configuration > Static VLAN Setup

The following table describes the related labels in this screen.

Table 38 Advanced Application > VLAN > VLAN Configuration > Static VLAN Setup

LABEL DESCRIPTION

ACTIVE Select this check box to activate the VLAN settings.

Name Enter a descriptive name for the VLAN group for identification purposes. This name consists of up

to 64 printable characters. Spaces are allowed.

VLAN Group ID Enter the VLAN ID for this static entry; the valid range is between 1 and 4094.

Port The port number identifies the port you are configuring.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Control Select Normal for the port to dynamically join this VLAN group using GVRP. This is the default

selection.

Select Fixed for the port to be a permanent member of this VLAN group.

Select Forbidden if you want to prohibit the port from joining this VLAN group.

Tagging Select TX Tagging if you want the port to tag all outgoing frames transmitted with this VLAN

Group ID.

Add Click Add to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to change the fields back to their last saved values.

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9.5 Configure VLAN Port Setting

Use the VLAN Port Setup screen to configure the static VLAN (IEEE 802.1Q) settings on a port. Click the

VLAN Port Setup link in the VLAN Configuration screen.

Figure 96 Advanced Application > VLAN > VLAN Configuration > VLAN Port Setup

The following table describes the labels in this screen.

Clear Click Clear to start configuring the screen again.

VID This field displays the ID number of the VLAN group. Click the number to edit the VLAN settings.

Active This field indicates whether the VLAN settings are enabled (Yes) or disabled (No).

Name This field displays the descriptive name for this VLAN group.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Click Delete to remove the selected entry from the summary table.

Cancel Click Cancel to clear the check boxes.

Table 38 Advanced Application > VLAN > VLAN Configuration > Static VLAN Setup (continued)

LABEL DESCRIPTION

Table 39 Advanced Application > VLAN > VLAN Configuration> VLAN Port Setup

LABEL DESCRIPTION

GVRP GVRP (GARP VLAN Registration Protocol) is a registration protocol that defines a way for

switches to register necessary VLAN members on ports across the network.

Select this check box to permit VLAN groups beyond the local Switch.

Port This field displays the port number.

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9.6 Subnet Based VLANs

Subnet based VLANs allow you to group traffic into logical VLANs based on the source IP subnet you

specify. When a frame is received on a port, the Switch checks if a tag is added already and the IP

subnet it came from. The untagged packets from the same IP subnet are then placed in the same

subnet based VLAN. One advantage of using subnet based VLANs is that priority can be assigned to

traffic from the same IP subnet.

For example, an ISP (Internet Services Provider) may divide different types of services it provides to

customers into different IP subnets. Traffic for voice services is designated for IP subnet 172.16.1.0/24,

video for 192.168.1.0/24 and data for 10.1.1.0/24. The Switch can then be configured to group incoming

traffic based on the source IP subnet of incoming frames.

You configure a subnet based VLAN with priority 6 and VID of 100 for traffic received from IP subnet

172.16.1.0/24 (voice services). You also have a subnet based VLAN with priority 5 and VID of 200 for

traffic received from IP subnet 192.168.1.0/24 (video services). Lastly, you configure VLAN with priority 3

and VID of 300 for traffic received from IP subnet 10.1.1.0/24 (data services). All untagged incoming

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Ingress Check If this check box is selected, the Switch discards incoming frames on a port for VLANs that do

not include this port in its member set.

Clear this check box to disable ingress filtering.

PVID A PVID (Port VLAN ID) is a tag that adds to incoming untagged frames received on a port so

that the frames are forwarded to the VLAN group that the tag defines.

Enter a number between 1and 4094 as the port VLAN ID.

GVRP Select this check box to allow GVRP on this port.

Acceptable

Frame Type

Specify the type of frames allowed on a port. Choices are All, Tag Only and Untag Only.

Select All from the drop-down list box to accept all untagged or tagged frames on this port.

This is the default setting.

Select Tag Only to accept only tagged frames on this port. All untagged frames will be

dropped.

Select Untag Only to accept only untagged frames on this port. All tagged frames will be

dropped.

VLAN Trunking Enable VLAN Trunking on ports connected to other switches or routers (but not ports directly

connected to end users) to allow frames belonging to unknown VLAN groups to pass through

the Switch.

Isolation Select this to allows this port to communicate only with the CPU management port and the

ports on which the isolation feature is not enabled.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 39 Advanced Application > VLAN > VLAN Configuration> VLAN Port Setup

LABEL DESCRIPTION

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frames will be classified based on their source IP subnet and prioritized accordingly. That is video

services receive the highest priority and data the lowest.

Figure 97 Subnet Based VLAN Application Example

9.6.1 Configuring Subnet Based VLAN

Click the Subnet Based VLAN Setup link in the VLAN Configuration screen to display the configuration

screen as shown.

Note: Subnet based VLAN applies to un-tagged packets and is applicable only when you use

IEEE 802.1Q tagged VLAN.

Figure 98 Advanced Application > VLAN > VLAN Configuration > Subnet Based VLAN Setup

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The following table describes the labels in this screen.

9.7 Protocol Based VLANs

Protocol based VLANs allow you to group traffic into logical VLANs based on the protocol you specify.

When an upstream frame is received on a port (configured for a protocol based VLAN), the Switch

checks if a tag is added already and its protocol. The untagged packets of the same protocol are then

placed in the same protocol based VLAN. One advantage of using protocol based VLANs is that priority

can be assigned to traffic of the same protocol.

Table 40 Advanced Application > VLAN > VLAN Configuration > Subnet Based VLAN Setup

LABEL DESCRIPTION

Active Check this box to activate this subnet based VLANs on the Switch.

DHCP-Vlan

Override

When DHCP snooping is enabled DHCP clients can renew their IP address through the DHCP

VLAN or via another DHCP server on the subnet based VLAN.

Select this check box to force the DHCP clients in this IP subnet to obtain their IP addresses

through the DHCP VLAN.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Active Check this box to activate the IP subnet VLAN you are creating or editing.

Name Enter up to 32 alpha numeric characters to identify this subnet based VLAN.

IP Enter the IP address of the subnet for which you want to configure this subnet based VLAN.

Mask-Bits Enter the bit number of the subnet mask. To find the bit number, convert the subnet mask to

binary format and add all the 1’s together. Take “255.255.255.0” for example. 255 converts to

eight 1s in binary. There are three 255s, so add three eights together and you get the bit

number (24).

VID Enter Enter the ID of a VLAN with which the untagged frames from the IP subnet specified in this

subnet based VLAN are tagged. This must be an existing VLAN which you defined in the

Advanced Applications > VLAN screens.

Priority Select the priority level that the Switch assigns to frames belonging to this VLAN.

Add Click Add to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Index This is the index number identifying this subnet based VLAN. Click on any of these numbers to

edit an existing subnet based VLAN.

Active This field shows whether the subnet based VLAN is active or not.

Name This field shows the name the subnet based VLAN.

IP This field shows the IP address of the subnet for this subnet based VLAN.

Mask-Bits This field shows the subnet mask in bit number format for this subnet based VLAN.

VID This field shows the VLAN ID of the frames which belong to this subnet based VLAN.

Priority This field shows the priority which is assigned to frames belonging to this subnet based VLAN.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Click this to delete the subnet based VLANs which you marked for deletion.

Cancel Click Cancel to clear the check boxes.

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Note: Protocol based VLAN applies to un-tagged packets and is applicable only when you

use IEEE 802.1Q tagged VLAN.

For example, port 1, 2, 3 and 4 belong to static VLAN 100, and port 4, 5, 6, 7 belong to static VLAN 120.

You configure a protocol based VLAN A with priority 3 for ARP traffic received on port 1, 2 and 3. You

also have a protocol based VLAN B with priority 2 for Apple Talk traffic received on port 6 and 7. All

upstream ARP traffic from port 1, 2 and 3 will be grouped together, and all upstream Apple Talk traffic

from port 6 and 7 will be in another group and have higher priority than ARP traffic, when they go

through the uplink port to a backbone switch C.

Figure 99 Protocol Based VLAN Application Example

9.7.1 Configuring Protocol Based VLAN

Click the Protocol Based VLAN Setup link in the VLAN Configuration screen to display the configuration

screen as shown.

Note: Protocol-based VLAN applies to un-tagged packets and is applicable only when you

use IEEE 802.1Q tagged VLAN.

Figure 100 Advanced Application > VLAN > VLAN Configuration > Protocol Based VLAN Setup

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The following table describes the labels in this screen.

9.8 Voice VLAN Setup

Voice VLAN ensures that the sound quality of an IP phone is preserved from deteriorating when the data

traffic on the Switch ports is high. It groups the voice traffic with defined priority into an assigned VLAN

which enables the separation of voice and data traffic coming onto the Switch port.

You can set priority level to the Voice VLAN and add MAC address of IP phones from specific

manufacturers by using its ID from the Organizationally Unique Identifiers (OUI).

Click the Voice VLAN Setup link in the VLAN Configuration screen to display the configuration screen as

shown.

Table 41 Advanced Application > VLAN > VLAN Configuration > Protocol Based VLAN Setup

LABEL DESCRIPTION

Active Check this box to activate this protocol based VLAN.

Port Type a port to be included in this protocol based VLAN.

This port must belong to a static VLAN in order to participate in a protocol based VLAN. See

Chapter 9 on page 110 for more details on setting up VLANs.

Name Enter up to 32 alpha numeric characters to identify this protocol based VLAN.

Ethernet-type Use the drop down list box to select a predefined protocol to be included in this protocol

based VLAN or select Others and type the protocol number in hexadecimal notation. For

example the IP protocol in hexadecimal notation is 0800, and Novell IPX protocol is 8137.

Note: Protocols in the hexadecimal number range of 0x0000 to 0x05ff are not

allowed to be used for protocol based VLANs.

VID Enter the ID of a VLAN to which the port belongs. This must be an existing VLAN which you

defined in the Advanced Applications > VLAN screens.

Priority Select the priority level that the Switch will assign to frames belonging to this VLAN.

Add Click Add to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Index This is the index number identifying this protocol based VLAN. Click on any of these numbers

to edit an existing protocol based VLAN.

Active This field shows whether the protocol based VLAN is active or not.

Port This field shows which port belongs to this protocol based VLAN.

Name This field shows the name the protocol based VLAN.

Ethernet-type This field shows which Ethernet protocol is part of this protocol based VLAN.

VID This field shows the VLAN ID of the port.

Priority This field shows the priority which is assigned to frames belonging to this protocol based

VLAN.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in

the table heading row to select all entries.

Delete Click this to delete the protocol based VLANs which you marked for deletion.

Cancel Click Cancel to clear the check boxes.

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Figure 101 Advanced Application > VLAN > VLAN Configuration > Voice VLAN Setup

The following table describes the fields in the above screen.

Table 42 Advanced Application > VLAN > VLAN Configuration > Voice VLAN Setup

LABEL DESCRIPTION

Voice VLAN Global Setup

Voice VLAN Click the second radio button if you want to enable the Voice VLAN feature. Type a

VLAN ID number in the box next to the radio button that is associated with the Voice

VLAN. You also need to create a static VLAN with the same VID in the Static VLAN Setup

screen, and then connect the IP phone with the specified OUI MAC address to a port

that joins the static VLAN

Click the Disable radio button if you do not want to enable the Voice VLAN feature.

Priority Select the priority level of the Voice VLAN from 0 to 7. Default setting is 5.The higher the

numeric value you assign, the higher the priority for this Voice VLAN.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel

to save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Clear Click Clear to reset the fields to default settings.

Voice VLAN OUI Setup

OUI address Type the IP Phone manufacturer’s OUI MAC address. The first three byes is the

manufacturer identifier, the last three bytes is a unique station ID.

OUI mask Type the mask for the specified IP Phone manufacturer’s OUI MAC address to determine

which bits a packet’s MAC address should match.

Enter “f” for each bit of the specified MAC address that the traffic’s MAC address should

match. Enter “0” for the bit(s) of the matched traffic’s MAC address, which can be of any

hexadecimal character(s). For example, if you set the MAC address to 00:13:49:00:00:00

and the mask to ff:ff:ff:00:00:00, a packet with a MAC address of 00:13:49:12:34:56

matches this criteria.

Description Type an description up to 32 characters for the Voice VLAN device. For example:

Siemens.

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9.9 MAC Based VLAN

The MAC-based VLAN feature assigns incoming untagged packets to a VLAN and classifies the traffic

based on the source MAC address of the packet. When untagged packets arrive at the switch, the

source MAC address of the packet is looked up in a MAC to VLAN mapping table. If an entry is found,

the corresponding VLAN ID is assigned to the packet. The assigned VLAN ID is verified against the VLAN

table. If the VLAN is valid, ingress processing on the packet continues; otherwise, the packet is dropped.

This feature allows users to change ports without having to reconfigure the VLAN. You can assign priority

to the MAC-based VLAN and define a MAC to VLAN mapping table by entering a specified source

MAC address in the MAC-based VLAN setup screen. You can also delete a MAC-based VLAN entry in

the same screen.

Click the MAC Based VLAN Setup link in the VLAN Configuration screen to see the following screen.

Figure 102 Advanced Application > VLAN > VLAN Configuration > MAC Based VLAN Setup

Add Click Add to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel

to save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Index This field displays the index number of the Voice VLAN.

OUI address This field displays the OUI address of the Voice VLAN.

OUI mask This field displays the OUI mask address of the Voice VLAN.

Description This field displays the description of the Voice VLAN with OUI address.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in

the table heading row to select all entries.

Delete Click Delete to remove the selected entry from the summary table.

Cancel Click Cancel to clear the check boxes.

Table 42 Advanced Application > VLAN > VLAN Configuration > Voice VLAN Setup

LABEL DESCRIPTION

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The following table describes the fields in the above screen.

9.10 Vendor ID Based VLAN

The Vendor ID based VLAN feature assigns incoming untagged packets to a VLAN and classifies the

traffic based on the source MAC address of the packet. When untagged packets arrive at the switch,

the source MAC address of the packet is looked up in a Vendor ID to VLAN mapping table. If an entry is

found, the corresponding VLAN ID is assigned to the packet. The assigned VLAN ID is verified against the

VLAN table. If the VLAN is valid, ingress processing on the packet continues; otherwise, the packet is

dropped.

This feature allows users to change ports without having to reconfigure the VLAN. You can assign a

802.1p priority to the vendor ID based VLAN and define a vendor ID to VLAN mapping table by entering

a specified source MAC address and mask in the vendor ID based VLAN setup screen. You can also

delete a vendor ID based VLAN entry in the same screen.

For every vendor ID based VLAN rule you set, you can specify a weight number to define the rule’s

priority level. As rules are processed one after the other, stating a priority order will let you choose which

rule has to be applied first and which second.

Click the Vendor ID Based VLAN Setup link in the VLAN Configuration screen to see the following screen.

Table 43 Advanced Application > VLAN > VLAN Configuration > MAC Based VLAN Setup

LABEL DESCRIPTION

Name Type a name up to 32 alpha numeric characters for the MAC-based VLAN entry.

MAC Address Type a MAC address that is bind to the MAC-based VLAN entry. This is the source MAC

address of the data packet that is looked up when untagged packets arrive at the Switch.

VID Type an ID (from 1 to 4094) for the VLAN ID that is associated with the MAC-based VLAN

entry.

Priority Type a priority (0-7) for the MAC-based VLAN entry.The higher the numeric value you

assign, the higher the priority for this MAC-based VLAN entry.

Add Click Add to save the new MAC-based VLAN entry.

Cancel Click Cancel to clear the fields in the MAC-based VLAN entry.

Index This field displays the index number of the MAC-based VLAN entry.

Name This field displays the name of the MAC-based VLAN entry.

MAC Address This field displays the source MAC address that is bind to the MAC-based VLAN entry.

VID This field displays the VLAN ID of the MAC-based VLAN entry.

Priority This field displays the priority level of the MAC-based VLAN entry.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in

the table heading row to select all entries.

Delete Click Delete to remove the selected entry from the summary table.

Cancel Click Cancel to clear the check boxes.

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Figure 103 Advanced Application > VLAN > VLAN Configuration > Vendor ID Based VLAN Setup

The following table describes the fields in the above screen.

Table 44 Advanced Application > VLAN > VLAN Configuration > Vendor ID Based VLAN Setup

LABEL DESCRIPTION

Name Type a name up to 32 alpha numeric characters for the vendor ID based VLAN entry.

MAC address Type a MAC address that is bind to the vendor ID-based VLAN entry. This is the source MAC

address of the data packet that is looked up when untagged packets arrive at the Switch.

Mask Type the mask for the specified source MAC address to determine which bits a packet’s

MAC address should match.

Enter “f” for each bit of the specified MAC address that the traffic’s MAC address should

match. Enter “0” for the bit(s) of the matched traffic’s MAC address, which can be of any

hexadecimal character(s). For example, if you set the MAC address to 00:13:49:00:00:00

and the mask to ff:ff:ff:00:00:00, a packet with a MAC address of 00:13:49:12:34:56 matches

this criteria.

VLAN Type an ID (from 1 to 4094) for the VLAN that is associated with the vendor ID based VLAN

entry.

Priority Select the priority level that the Switch assigns to frames belonging to this VLAN. The higher

the numeric value you assign, the higher the priority for this vendor ID based VLAN entry.

Weight Enter a number between 0 and 255 to specify the rule’s weight. This is to decide the priority

in which the rule is applied. The higher the number, the higher the rule’s priority.

Add Click Add to save the new vendor ID based VLAN entry.

Cancel Click Cancel to clear the fields in the vendor ID based VLAN entry.

Index This field displays the index number of the vendor ID based VLAN entry.

Name This field displays the name of the vendor ID based VLAN entry.

MAC address This field displays the source MAC address that is bind to the vendor ID based VLAN entry.

Mask This field displays the mask for the source MAC address that is bind to the vendor ID based

VLAN entry.

VLAN This field displays the VLAN ID of the vendor ID based VLAN entry.

Priority This field displays the priority level which is assigned to frames belonging to this vendor ID

based VLAN.

Weight This field displays the weight of the vendor ID based VLAN entry.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in

the table heading row to select all entries.

Delete Click Delete to remove the selected entry from the summary table.

Cancel Click Cancel to clear the check boxes.

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9.11 Port-Based VLAN Setup

Port-based VLANs are VLANs where the packet forwarding decision is based on the destination MAC

address and its associated port.

Port-based VLANs require allowed outgoing ports to be defined for each port. Therefore, if you wish to

allow two subscriber ports to talk to each other, for example, between conference rooms in a hotel, you

must define the egress (an egress port is an outgoing port, that is, a port through which a data packet

leaves) for both ports.

Port-based VLANs are specific only to the Switch on which they were created.

Note: When you activate port-based VLAN, the Switch uses a default VLAN ID of 1. You

cannot change it.

Note: In screens (such as IP Setup and Filtering) that require a VID, you must enter 1 as the VID.

The port-based VLAN setup screen is shown next. The CPU management port forms a VLAN with all

Ethernet ports.

9.11.1 Configure a Port Based VLAN

Select Port Based as the VLAN Type in the Basic Setting > Switch Setup screen and then click Advanced

Application > VLAN from the navigation panel to display the next screen.

Figure 104 Advanced Application > VLAN: Port Based VLAN Setup (All Connected)

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Figure 105 Advanced Application > VLAN: Port Based VLAN Setup (Port Isolation)

The following table describes the labels in this screen.

Table 45 Advanced Application > VLAN: Port Based VLAN Setup

LABEL DESCRIPTION

Setting Wizard Choose All conne cted or Port isolation.

All connected means all ports can communicate with each other, that is, there are no virtual

LANs. All incoming and outgoing ports are selected. This option is the most flexible but also the

least secure.

Port isolation means that each port can only communicate with the CPU management port

and cannot communicate with each other. All incoming ports are selected while only the

CPU outgoing port is selected. This option is the most limiting but also the most secure.

After you make your selection, click Apply (top right of screen) to display the screens as

mentioned above. You can still customize these settings by adding/deleting incoming or

outgoing ports, but you must also click Apply at the bottom of the screen.

Incoming These are the ingress ports; an ingress port is an incoming port, that is, a port through which a

data packet enters. If you wish to allow two subscriber ports to talk to each other, you must

define the ingress port for both ports. The numbers in the top row denote the incoming port for

the corresponding port listed on the left (its outgoing port). CPU refers to the Switch

management port. By default it forms a VLAN with all Ethernet ports. If it does not form a VLAN

with a particular port then the Switch cannot be managed from that port

Outgoing These are the egress ports; an egress port is an outgoing port, that is, a port through which a

data packet leaves. If you wish to allow two subscriber ports to talk to each other, you must

define the egress port for both ports. CPU refers to the Switch management port. By default it

forms a VLAN with all Ethernet ports. If it does not form a VLAN with a particular port then the

Switch cannot be managed from that port.

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Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 45 Advanced Application > VLAN: Port Based VLAN Setup

LABEL DESCRIPTION

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CHAPTER 10

Static MAC Forward Setup

10.1 Overview

This chapter discusses how to configure forwarding rules based on MAC addresses of devices on your

network.

Use these screens to configure static MAC address forwarding.

10.1.1 What You Can Do

Use the Static MAC Forwarding screen (Section 10.2 on page 131) to assign static MAC addresses for a

port.

10.2 Configuring Static MAC Forwarding

A static MAC address is an address that has been manually entered in the MAC address table. Static

MAC addresses do not age out. When you set up static MAC address rules, you are setting static MAC

addresses for a port. This may reduce the need for broadcasting.

Static MAC address forwarding together with port security allow only computers in the MAC address

table on a port to access the Switch. See Chapter 19 on page 181 for more information on port security.

Click Advanced Application > Static MAC Forwarding in the navigation panel to display the

configuration screen as shown.

Figure 106 Advanced Application > Static MAC Forwarding

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The following table describes the labels in this screen.

Table 46 Advanced Application > Static MAC Forwarding

LABEL DESCRIPTION

Active Select this check box to activate your rule. You may temporarily deactivate a rule without

deleting it by clearing this check box.

Name Enter a descriptive name for identification purposes for this static MAC address forwarding rule.

MAC Address Enter the MAC address in valid MAC address format, that is, six hexadecimal character pairs.

Note: Static MAC addresses do not age out.

VID Enter the VLAN identification number.

Port Enter the port where the MAC address entered in the previous field will be automatically

forwarded.

Add Click Add to save your rule to the Switch’s run-time memory. The Switch loses this rule if it is turned

off or loses power, so use the Save link on the top navigation panel to save your changes to the

non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to their last saved values.

Clear Click Clear to begin configuring this screen afresh.

Index Click an index number to modify a static MAC address rule for a port.

Active This field displays whether this static MAC address forwarding rule is active (Yes) or not (No). You

may temporarily deactivate a rule without deleting it.

Name This field displays the descriptive name for identification purposes for this static MAC address-

forwarding rule.

MAC Address This field displays the MAC address that will be forwarded and the VLAN identification number to

which the MAC address belongs.

VID This field displays the ID number of the VLAN group.

Port This field displays the port where the MAC address shown in the next field will be forwarded.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the table

heading row to select all entries.

Delete Click Delete to remove the selected entry from the summary table.

Cancel Click Cancel to clear the check boxes.

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CHAPTER 11

Static Multicast Forwarding

11.1 Static Multicast Forward Setup Overview

This chapter discusses how to configure forwarding rules based on multicast MAC addresses of devices

on your network.

Use these screens to configure static multicast address forwarding.

11.1.1 What You Can Do

Use the Static Multicast Forwarding screen (Section 11.2 on page 134) to configure rules to forward

specific multicast frames, such as streaming or control frames, to specific port(s).

11.1.2 What You Need To Know

A multicast MAC address is the MAC address of a member of a multicast group. A static multicast

address is a multicast MAC address that has been manually entered in the multicast table. Static

multicast addresses do not age out. Static multicast forwarding allows you (the administrator) to forward

multicast frames to a member without the member having to join the group first.

If a multicast group has no members, then the switch will either flood the multicast frames to all ports or

drop them. Figure 107 on page 133 shows such unknown multicast frames flooded to all ports. With static

multicast forwarding, you can forward these multicasts to port(s) within a VLAN group. Figure 108 on

page 134 shows frames being forwarded to devices connected to port 3. Figure 109 on page 134 shows

frames being forwarded to ports 2 and 3 within VLAN group 4.

Figure 107 No Static Multicast Forwarding

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Figure 108 Static Multicast Forwarding to A Single Port

Figure 109 Static Multicast Forwarding to Multiple Ports

11.2 Configuring Static Multicast Forwarding

Use this screen to configure rules to forward specific multicast frames, such as streaming or control

frames, to specific port(s).

Click Advanced Application > Static Multicast Forwarding to display the configuration screen as shown.

Figure 110 Advanced Application > Static Multicast Forwarding

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The following table describes the labels in this screen.

Table 47 Advanced Application > Static Multicast Forwarding

LABEL DESCRIPTION

Active Select this check box to activate your rule. You may temporarily deactivate a rule without

deleting it by clearing this check box.

Name Type a descriptive name (up to 32 printable ASCII characters) for this static multicast MAC

address forwarding rule. This is for identification only.

MAC Address Enter a multicast MAC address which identifies the multicast group. The last binary bit of the first

octet pair in a multicast MAC address must be 1. For example, the first octet pair 00000001 is 01

and 00000011 is 03 in hexadecimal, so 01:00:5e:00:00:0A and 03:00:5e:00:00:27 are valid multicast

MAC addresses.

VID You can forward frames with matching destination MAC address to port(s) within a VLAN group.

Enter the ID that identifies the VLAN group here. If you don’t have a specific target VLAN, enter 1.

Port Enter the port(s) where frames with destination MAC address that matched the entry above are

forwarded. You can enter multiple ports separated by (no space) comma (,) or hyphen (-). For

example, enter “3-5” for ports 3, 4, and 5. Enter “3,5,7” for ports 3, 5, and 7.

Add Click Add to save your rule to the Switch’s run-time memory. The Switch loses this rule if it is turned

off or loses power, so use the Save link on the top navigation panel to save your changes to the

non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to their last saved values.

Clear Click Clear to begin configuring this screen afresh.

Index Click an index number to modify a static multicast MAC address rule for port(s).

Active This field displays whether a static multicast MAC address forwarding rule is active (Yes) or not

(No). You may temporarily deactivate a rule without deleting it.

Name This field displays the descriptive name for identification purposes for a static multicast MAC

address-forwarding rule.

MAC Address This field displays the multicast MAC address that identifies a multicast group.

VID This field displays the ID number of a VLAN group to which frames containing the specified

multicast MAC address will be forwarded.

Port This field displays the port(s) within a identified VLAN group to which frames containing the

specified multicast MAC address will be forwarded.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Click Delete to remove the selected entry from the summary table.

Cancel Click Cancel to clear the check boxes.

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CHAPTER 12

Filtering

12.1 Filtering Overview

This chapter discusses MAC address port filtering.

Filtering means sifting traffic going through the Switch based on the source and/or destination MAC

addresses and VLAN group (ID).

12.1.1 What You Can Do

Use the Filtering screen (Section 12.2 on page 136) to create rules for traffic going through the Switch.

12.2 Configure a Filtering Rule

Use this screen to create rules for traffic going through the Switch. Click Advanced Application > Filtering

in the navigation panel to display the screen as shown next.

Figure 111 Advanced Application > Filtering

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The following table describes the related labels in this screen.

Table 48 Advanced Application > Filtering

LABEL DESCRIPTION

Active Make sure to select this check box to activate your rule. You may temporarily deactivate a rule

without deleting it by deselecting this check box.

Name Type a descriptive name (up to 32 printable ASCII characters) for this rule. This is for identification

only.

Action Select Discard source to drop the frames from the source MAC address (specified in the MAC field).

The Switch can still send frames to the MAC address.

Select Discard destination to drop the frames to the destination MAC address (specified in the MAC

address). The Switch can still receive frames originating from the MAC address.

Select Discard source and Discard destination to block traffic to/from the MAC address specified in

the MAC field.

MAC Type a MAC address in valid MAC address format, that is, six hexadecimal character pairs.

VID Type the VLAN group identification number.

Add Click Add to save your changes to the Switch’s run-time memory. The Switch loses these changes if

it is turned off or loses power, so use the Save link on the top navigation panel to save your changes

to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to your previous configuration.

Clear Click Clear to clear the fields to the factory defaults.

Index This field displays the index number of the rule. Click an index number to change the settings.

Active This field displays Yes when the rule is activated and No when is it deactivated.

Name This field displays the descriptive name for this rule. This is for identification purpose only.

MAC Address This field displays the source/destination MAC address with the VLAN identification number to

which the MAC address belongs.

VID This field displays the VLAN group identification number.

Action This field displays Discard source, Discard destination, or Discard both depending on what you

configured above.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the table

heading row to select all entries.

Delete Check the rule(s) that you want to remove and then click the Delete button.

Cancel Click Cancel to clear the selected checkbox(es).

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CHAPTER 13

Spanning Tree Protocol

13.1 Spanning Tree Protocol Overview

The Switch supports Spanning Tree Protocol (STP), Rapid Spanning Tree Protocol (RSTP) and Multiple

Spanning Tree Protocol (MSTP) as defined in the following standards.

• IEEE 802.1D Spanning Tree Protocol

• IEEE 802.1w Rapid Spanning Tree Protocol

• IEEE 802.1s Multiple Spanning Tree Protocol

The Switch also allows you to set up multiple STP configurations (or trees). Ports can then be assigned to

the trees.

13.1.1 What You Can Do

• Use the Spanning Tree Protocol Status screen (Section 13.2 on page 141) to view the STP status in the

different STP modes (RSTP, MRSTP or MSTP) you can configure on the Switch.

• Use the Spanning Tree Configuration screen (Section 13.3 on page 142) to activate one of the STP

modes on the Switch.

• Use the Rapid Spanning Tree Protocol screen (Section 13.4 on page 142) to configure RSTP settings.

• Use the Rapid Spanning Tree Protocol Status screen (Section 13.5 on page 144) to view the RSTP status.

• Use the Multiple Spanning Tree Protocol screen (Section 13.6 on page 146) to configure MSTP.

• Use the Multiple Spanning Tree Protocol Status screen (Section 13.7 on page 150) to view the MSTP

status.

• Use the Multiple Rapid Spanning Tree Protocol screen (Section 13.8 on page 153) to configure MRSTP.

• Use the Multiple Rapid Spanning Tree Protocol Status screen (Section 13.9 on page 155) to view the

MRSTP status.

13.1.2 What You Need to Know

Read on for concepts on STP that can help you configure the screens in this chapter.

(Rapid) Spanning Tree Protocol

(R)STP detects and breaks network loops and provides backup links between switches, bridges or

routers. It allows a switch to interact with other (R)STP -compliant switches in your network to ensure that

only one path exists between any two stations on the network.

The Switch uses IEEE 802.1w RSTP (Rapid Spanning Tree Protocol) that allows faster convergence of the

spanning tree than STP (while also being backwards compatible with STP-only aware bridges). In RSTP,

topology change information is directly propagated throughout the network from the device that

generates the topology change. In STP, a longer delay is required as the device that causes a topology

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change first notifies the root bridge that then notifies the network. Both RSTP and STP flush unwanted

learned addresses from the filtering database. In RSTP, the port states are Discarding, Learning, and

Forwarding.

Note: In this user’s guide, “STP” refers to both STP and RSTP.

STP Terminology

The root bridge is the base of the spanning tree.

Path cost is the cost of transmitting a frame onto a LAN through that port. The recommended cost is

assigned according to the speed of the link to which a port is attached. The slower the media, the

higher the cost.

On each bridge, the root port is the port through which this bridge communicates with the root. It is the

port on this switch with the lowest path cost to the root (the root path cost). If there is no root port, then

this switch has been accepted as the root bridge of the spanning tree network.

For each LAN segment, a designated bridge is selected. This bridge has the lowest cost to the root

among the bridges connected to the LAN.

How STP Works

After a bridge determines the lowest cost-spanning tree with STP, it enables the root port and the ports

that are the designated ports for connected LANs, and disables all other ports that participate in STP.

Network packets are therefore only forwarded between enabled ports, eliminating any possible

network loops.

STP-aware switches exchange Bridge Protocol Data Units (BPDUs) periodically. When the bridged LAN

topology changes, a new spanning tree is constructed.

Once a stable network topology has been established, all bridges listen for Hello BPDUs (Bridge Protocol

Data Units) transmitted from the root bridge. If a bridge does not get a Hello BPDU after a predefined

interval (Max Age), the bridge assumes that the link to the root bridge is down. This bridge then initiates

negotiations with other bridges to reconfigure the network to re-establish a valid network topology.

Table 49 STP Path Costs

LINK SPEED RECOMMENDED VALUE RECOMMENDED RANGE ALLOWED RANGE

Path Cost 4Mbps 250 100 to 1000 1 to 65535

Path Cost 10Mbps 100 50 to 600 1 to 65535

Path Cost 16Mbps 62 40 to 400 1 to 65535

Path Cost 100Mbps 19 10 to 60 1 to 65535

Path Cost 1Gbps 4 3 to 10 1 to 65535

Path Cost 10Gbps 2 1 to 5 1 to 65535

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STP Port States

STP assigns five port states to eliminate packet looping. A bridge port is not allowed to go directly from

blocking state to forwarding state so as to eliminate transient loops.

Multiple STP

Multiple Spanning Tree Protocol (IEEE 802.1s) is backward compatible with STP/RSTP and addresses the

limitations of existing spanning tree protocols (STP and RSTP) in networks to include the following

features:

• One Common and Internal Spanning Tree (CIST) that represents the entire network’s connectivity.

• Grouping of multiple bridges (or switching devices) into regions that appear as one single bridge on

the network.

• A VLAN can be mapped to a specific Multiple Spanning Tree Instance (MSTI). MSTI allows multiple

VLANs to use the same spanning tree.

• Load-balancing is possible as traffic from different VLANs can use distinct paths in a region.

Multiple RSTP

MRSTP (Multiple RSTP) is Zyxel’s proprietary feature that is compatible with RSTP and STP. With MRSTP, you

can have more than one spanning tree on your Switch and assign port(s) to each tree. Each spanning

tree operates independently with its own bridge information.

In the following example, there are two RSTP instances (MRSTP 1 and MRSTP2) on switch A.

To set up MRSTP, activate MRSTP on the Switch and specify which port(s) belong to which spanning tree.

Note: Each port can belong to one STP tree only.

Table 50 STP Port States

PORT STATE DESCRIPTION

Disabled STP is disabled (default).

Blocking Only configuration and management BPDUs are received and processed.

Listening All BPDUs are received and processed.

Note: The listening state does not exist in RSTP.

Learning All BPDUs are received and processed. Information frames are submitted to the learning process

but not forwarded.

Forwarding All BPDUs are received and processed. All information frames are received and forwarded.

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Figure 112 MRSTP Network Example

Multiple STP

Multiple Spanning Tree Protocol (IEEE 802.1s) is backward compatible with STP/RSTP and addresses the

limitations of existing spanning tree protocols (STP and RSTP) in networks to include the following

features:

• One Common and Internal Spanning Tree (CIST) that represents the entire network’s connectivity.

• Grouping of multiple bridges (or switching devices) into regions that appear as one single bridge on

the network.

• A VLAN can be mapped to a specific Multiple Spanning Tree Instance (MSTI). MSTI allows multiple

VLANs to use the same spanning tree.

• Load-balancing is possible as traffic from different VLANs can use distinct paths in a region.

13.2 Spanning Tree Protocol Status Screen

The Spanning Tree Protocol status screen changes depending on what standard you choose to

implement on your network. Click Advanced Application > Spanning Tree Protocol to see the screen as

shown.

Figure 113 Advanced Application > Spanning Tree Protocol

This screen differs depending on which STP mode (RSTP or MSTP) you configure on the Switch. This screen

is described in detail in the section that follows the configuration section for each STP mode. Click

Configuration to activate one of the STP standards on the Switch.

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13.3 Spanning Tree Configuration

Use the Spanning Tree Configuration screen to activate one of the STP modes on the Switch. Click

Configuration in the Advanced Application > Spanning Tree Protocol.

Figure 114 Advanced Application > Spanning Tree Protocol > Configuration

The following table describes the labels in this screen.

13.4 Configure Rapid Spanning Tree Protocol

Use this screen to configure RSTP settings, see Section 13.1 on page 138 for more information on RSTP.

Click RSTP in the Advanced Application > Spanning Tree Protocol screen.

Table 51 Advanced Application > Spanning Tree Protocol > Configuration

LABEL DESCRIPTION

Spanning Tree

Mode

You can activate one of the STP modes on the Switch.

Select Rapid Spanning Tree, Multiple Rapid Spanning Tree or Multiple Spanning Tree. See

Section 13.1 on page 138 for background information on STP.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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Figure 115 Advanced Application > Spanning Tree Protocol > RSTP

The following table describes the labels in this screen.

Table 52 Advanced Application > Spanning Tree Protocol > RSTP

LABEL DESCRIPTION

Status Click Status to display the RSTP Status screen (see Figure 116 on page 145).

Active Select this check box to activate RSTP. Clear this check box to disable RSTP.

Note: You must also activate Rapid Spanning Tree in the Advanced Application >

Spanning Tree Protocol > Configuration screen to enable RSTP on the Switch.

Bridge Priority Bridge priority is used in determining the root switch, root port and designated port. The switch

with the highest priority (lowest numeric value) becomes the STP root switch. If all switches

have the same priority, the switch with the lowest MAC address will then become the root

switch. Select a value from the drop-down list box.

The lower the numeric value you assign, the higher the priority for this bridge.

Bridge Priority determines the root bridge, which in turn determines Hello Time, Max Age and

Forwarding Delay.

Hello Time This is the time interval in seconds between BPDU (Bridge Protocol Data Units) configuration

message generations by the root switch. The allowed range is 1 to 10 seconds.

Max Age This is the maximum time (in seconds) the Switch can wait without receiving a BPDU before

attempting to reconfigure. All Switch ports (except for designated ports) should receive BPDUs

at regular intervals. Any port that ages out STP information (provided in the last BPDU)

becomes the designated port for the attached LAN. If it is a root port, a new root port is

selected from among the Switch ports attached to the network. The allowed range is 6 to 40

seconds.

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13.5 Rapid Spanning Tree Protocol Status

Click Advanced Application > Spanning Tree Protocol in the navigation panel to display the status

screen as shown next. See Section 13.1 on page 138 for more information on RSTP.

Note: This screen is only available after you activate RSTP on the Switch.

Forwarding Delay This is the maximum time (in seconds) the Switch will wait before changing states. This delay is

required because every switch must receive information about topology changes before it

starts to forward frames. In addition, each port needs time to listen for conflicting information

that would make it return to a blocking state; otherwise, temporary data loops might result.

The allowed range is 4 to 30 seconds.

As a general rule:

Note: 2 * (Forward Delay - 1) >= Max Age >= 2 * (Hello Time + 1)

Port This field displays the port number. * means all ports.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select this check box to activate RSTP on this port.

Edge Select this check box to configure a port as an edge port when it is directly attached to a

computer. An edge port changes its initial STP port state from blocking state to forwarding

state immediately without going through listening and learning states right after the port is

configured as an edge port or when its link status changes.

Note: An edge port becomes a non-edge port as soon as it receives a Bridge

Protocol Data Unit (BPDU).

Root Guard Select this check box to enable root guard on this port in order to prevent the switch(es)

attached to the port from becoming the root bridge.

With root guard enabled, a port is blocked when the Switch receives a superior BPDU on it. The

Switch allows traffic to pass through this port again when the switch connected to the port

stops to send superior BPDUs.

Priority Configure the priority for each port here.

Priority decides which port should be disabled when more than one port forms a loop in a

switch. Ports with a higher priority numeric value are disabled first. The allowed range is

between 0 and 255 and the default value is 128.

Path Cost Path cost is the cost of transmitting a frame on to a LAN through that port. It is recommended

to assign this value according to the speed of the bridge. The slower the media, the higher the

cost - see Table 49 on page 139 for more information.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 52 Advanced Application > Spanning Tree Protocol > RSTP (continued)

LABEL DESCRIPTION

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Figure 116 Advanced Application > Spanning Tree Protocol > Status: RSTP

The following table describes the labels in this screen.

Table 53 Advanced Application > Spanning Tree Protocol > Status: RSTP

LABEL DESCRIPTION

Configuration Click Configuration to specify which STP mode you want to activate. Click RSTP to edit RSTP

settings on the Switch.

Bridge Root refers to the base of the spanning tree (the root bridge). Our Bridge is this switch. This

Switch may also be the root bridge.

Bridge ID This is the unique identifier for this bridge, consisting of bridge priority plus MAC address. This ID

is the same for Root and Our Bridge if the Switch is the root switch.

Hello Time

(second)

This is the time interval (in seconds) at which the root switch transmits a configuration

message. The root bridge determines Hello Time, Max Age and Forwarding Delay.

Max Age (second) This is the maximum time (in seconds) the Switch can wait without receiving a configuration

message before attempting to reconfigure.

Forwarding Delay

(second)

This is the time (in seconds) the root switch will wait before changing states (that is, listening to

learning to forwarding).

Note: The listening state does not exist in RSTP.

Cost to Bridge This is the path cost from the root port on this Switch to the root switch.

Port ID This is the priority and number of the port on the Switch through which this Switch must

communicate with the root of the Spanning Tree.

Topology

Changed Times

This is the number of times the spanning tree has been reconfigured.

Time Since Last

Change

This is the time since the spanning tree was last reconfigured.

Instance These fields display the MSTI to VLAN mapping. In other words, which VLANs run on each

spanning tree instance.

Port This field displays the number of the port on the Switch.

Port State This field displays the port state in STP.

•Discarding - The port does not forward/process received frames or learn MAC addresses,

but still listens for BPDUs.

•Learning - The port learns MAC addresses and processes BPDUs, but does not forward

frames yet.

•Forwarding - The port is operating normally. It learns MAC addresses, processes BPDUs and

forwards received frames.

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13.6 Configure Multiple Spanning Tree Protocol

To configure MSTP, click MSTP in the Advanced Application > Spanning Tree Protocol screen. See

Multiple STP on page 140 for more information on MSTP.

Port Role This field displays the role of the port in STP.

•Root - A forwarding port on a non-root bridge, which has the lowest path cost and is the

best port from the non-root bridge to the root bridge. A root bridge does not have a root

port.

•Designated - A forwarding port on the designated bridge for each connected LAN

segment. A designated bridge has the lowest path cost to the root bridge among the

bridges connected to the LAN segment. All the ports on a root bridge (root switch) are

designated ports.

•Alternate - A blocked port, which has a best alternate path to the root bridge. This path is

different from using the root port. The port moves to the forwarding state when the

designated port for the LAN segment fails.

•Backup - A blocked port, which has a backup/redundant path to a LAN segment where

a designated port is already connected when a switch has two links to the same LAN

segment.

•Disabled - Not strictly part of STP. The port can be disabled manually.

Designated Bridge

This field displays the identifier of the designated bridge to which this port belongs when the

port is a designated port. Otherwise, it displays the identifier of the designated bridge for the

LAN segment to which this port is connected.

Designated Port ID This field displays the priority and number of the bridge port (on the designated bridge),

through which the designated bridge transmits the stored configuration messages.

Designated Cost This field displays the path cost to the LAN segment to which the port is connected when the

port is a designated port. Otherwise, it displays the path cost to the root bridge from the

designated port for the LAN segment to which this port is connected,

Root Guard State This field displays the state of the port on which root guard is enabled.

•Root-inconsistent - the Switch receives superior BPDUs on the port and blocks the port.

•Forwarding - the Switch unblocks and allows the port to forward frames again.

Table 53 Advanced Application > Spanning Tree Protocol > Status: RSTP (continued)

LABEL DESCRIPTION

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Figure 117 Advanced Application > Spanning Tree Protocol > MSTP

The following table describes the labels in this screen.

Table 54 Advanced Application > Spanning Tree Protocol > MSTP

LABEL DESCRIPTION

Status Click Status to display the MSTP Status screen (see Figure 119 on page 151).

Port Click Port to display the MST P Port screen (see Figure 118 on page 149).

Active Select this to activate MSTP on the Switch. Clear this to disable MSTP on the Switch.

Note: You must also activate Multip le Spanning Tree in the Advanced Application >

Spanning Tree Protocol > Configuration screen to enable MSTP on the Switch.

Hello Time This is the time interval in seconds between BPDU (Bridge Protocol Data Units) configuration

message generations by the root switch. The allowed range is 1 to 10 seconds.

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Max Age This is the maximum time (in seconds) the Switch can wait without receiving a BPDU before

attempting to reconfigure. All Switch ports (except for designated ports) should receive BPDUs

at regular intervals. Any port that ages out STP information (provided in the last BPDU)

becomes the designated port for the attached LAN. If it is a root port, a new root port is

selected from among the Switch ports attached to the network. The allowed range is 6 to 40

seconds.

Forwarding Delay This is the maximum time (in seconds) the Switch will wait before changing states. This delay is

required because every switch must receive information about topology changes before it

starts to forward frames. In addition, each port needs time to listen for conflicting information

that would make it return to a blocking state; otherwise, temporary data loops might result.

The allowed range is 4 to 30 seconds. As a general rule:

Note: 2 * (Forward Delay - 1) >= Max Age >= 2 * (Hello Time + 1)

Maximum hops Enter the number of hops (between 1 and 255) in an MSTP region before the BPDU is discarded

and the port information is aged.

Configuration

Name

Enter a descriptive name (up to 32 characters) of an MST region.

Revision Number Enter a number to identify a region’s configuration. Devices must have the same revision

number to belong to the same region.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Instance Use this section to configure MSTI (Multiple Spanning Tree Instance) settings.

Instance Enter the number you want to use to identify this MST instance on the Switch.

Note: The Switch supports instance numbers 0-16.

Bridge Priority Set the priority of the Switch for the specific spanning tree instance. The lower the number, the

more likely the Switch will be chosen as the root bridge within the spanning tree instance.

Enter priority values between 0 and 61440 in increments of 4096 (thus valid values are 4096,

8192, 12288, 16384, 20480, 24576, 28672, 32768, 36864, 40960, 45056, 49152, 53248, 57344 and

61440).

VLAN Range Enter the start of the VLAN ID range that you want to add or remove from the VLAN range edit

area in the Start field. Enter the end of the VLAN ID range that you want to add or remove

from the VLAN range edit area in the End field.

Next click:

•Add - to add this range of VLAN(s) to be mapped to the MST instance.

•Remove - to remove this range of VLAN(s) from being mapped to the MST instance.

•Clear - to remove all VLAN(s) from being mapped to this MST instance.

Enabled VLAN(s) This field displays which VLAN(s) are mapped to this MST instance.

Port This field displays the port number. * means all ports.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select this check box to add this port to the MST instance.

Table 54 Advanced Application > Spanning Tree Protocol > MSTP (continued)

LABEL DESCRIPTION

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13.6.1 Multiple Spanning Tree Protocol Port Configuration

Click Advanced Application > Spanning Tree Protocol > MSTP > Port in the navigation panel to display

the status screen as shown next. See Multiple STP on page 140 for more information on MSTP.

Figure 118 Advanced Application > Spanning Tree Protocol > MSTP > Port

The following table describes the labels in this screen.

Priority Configure the priority for each port here.

Priority decides which port should be disabled when more than one port forms a loop in a

switch. Ports with a higher priority numeric value are disabled first. The allowed range is

between 0 and 255 and the default value is 128.

Path Cost Path cost is the cost of transmitting a frame on to a LAN through that port. It is recommended

to assign this value according to the speed of the bridge. The slower the media, the higher the

cost - see Table 49 on page 139 for more information.

Add Click Add to save this MST instance to the Switch’s run-time memory. The Switch loses this

change if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Instance This field displays the ID of an MST instance. Click this number to modify its settings.

VLAN This field displays the VID (or VID ranges) to which the MST instance is mapped.

Active Port This field display the ports configured to participate in the MST instance.

Select an entry’s check box to select a specific entry.

Delete Check the rule(s) that you want to remove and then click the Delete button.

Cancel Click Cancel to clear the selected checkbox(es).

Table 54 Advanced Application > Spanning Tree Protocol > MSTP (continued)

LABEL DESCRIPTION

Table 55 Advanced Application > Spanning Tree Protocol > MSTP > Port

LABEL DESCRIPTION

MSTP Click MSTP to edit MSTP settings on the Switch.

Port This field displays the port number. * means all ports.

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13.7 Multiple Spanning Tree Protocol Status

Click Advanced Application > Spanning Tree Protocol in the navigation panel to display the status

screen as shown next. See Multiple STP on page 140 for more information on MSTP.

Note: This screen is only available after you activate MSTP on the Switch.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to

set the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Edge Select this check box to configure a port as an edge port when it is directly attached to a

computer. An edge port changes its initial STP port state from blocking state to forwarding

state immediately without going through listening and learning states right after the port is

configured as an edge port or when its link status changes.

Note: An edge port becomes a non-edge port as soon as it receives a Bridge

Protocol Data Unit (BPDU).

Root Guard Select this check box to enable root guard on this port in order to prevent the switch(es)

attached to the port from becoming the root bridge.

With root guard enabled, a port is blocked when the Switch receives a superior BPDU on it.

The Switch allows traffic to pass through this port again when the switch connected to the

port stops to send superior BPDUs.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 55 Advanced Application > Spanning Tree Protocol > MSTP > Port (continued)

LABEL DESCRIPTION

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Figure 119 Advanced Application > Spanning Tree Protocol > Status: MSTP

The following table describes the labels in this screen.

Table 56 Advanced Application > Spanning Tree Protocol > Status: MSTP

LABEL DESCRIPTION

Configuration Click Configuration to specify which STP mode you want to activate. Click MSTP to edit MSTP

settings on the Switch.

CST This section describes the Common Spanning Tree settings.

Bridge Root refers to the base of the spanning tree (the root bridge). Our Bridge is this switch. This

Switch may also be the root bridge.

Bridge ID This is the unique identifier for this bridge, consisting of bridge priority plus MAC address. This ID

is the same for Root and Our Bridge if the Switch is the root switch.

Hello Time

(second)

This is the time interval (in seconds) at which the root switch transmits a configuration

message. The root bridge determines Hello Time, Max Age and Forwarding Delay.

Max Age (second) This is the maximum time (in seconds) the Switch can wait without receiving a configuration

message before attempting to reconfigure.

Forwarding Delay

(second)

This is the time (in seconds) the root switch will wait before changing states (that is, listening to

learning to forwarding).

Cost to Bridge This is the path cost from the root port on this Switch to the root switch.

Port ID This is the priority and number of the port on the Switch through which this Switch must

communicate with the root of the Spanning Tree.

Configuration

Name

This field displays the configuration name for this MST region.

Revision Number This field displays the revision number for this MST region.

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Configuration

Digest

A configuration digest is generated from the VLAN-MSTI mapping information.

This field displays the 16-octet signature that is included in an MSTP BPDU. This field displays the

digest when MSTP is activated on the system.

Topology

Changed Times

This is the number of times the spanning tree has been reconfigured.

Time Since Last

Change

This is the time since the spanning tree was last reconfigured.

Instance These fields display the MSTI to VLAN mapping. In other words, which VLANs run on each

spanning tree instance.

Instance This field displays the MSTI ID.

VLAN This field displays which VLANs are mapped to an MSTI.

MSTI Select the MST instance settings you want to view.

Bridge Root refers to the base of the MST instance. Our Bridge is this switch. This Switch may also be

the root bridge.

Bridge ID This is the unique identifier for this bridge, consisting of bridge priority plus MAC address. This ID

is the same for Root and Our Bridge if the Switch is the root switch.

Internal Cost This is the path cost from the root port in this MST instance to the regional root switch.

Port ID This is the priority and number of the port on the Switch through which this Switch must

communicate with the root of the MST instance.

Port This field displays the number of the port on the Switch.

Port State This field displays the port state in STP.

•Discarding - The port does not forward/process received frames or learn MAC addresses,

but still listens for BPDUs.

•Learning - The port learns MAC addresses and processes BPDUs, but does not forward

frames yet.

•Forwarding - The port is operating normally. It learns MAC addresses, processes BPDUs and

forwards received frames.

Port Role This field displays the role of the port in STP.

•Root - A forwarding port on a non-root bridge, which has the lowest path cost and is the

best port from the non-root bridge to the root bridge. A root bridge does not have a root

port.

•Designated - A forwarding port on the designated bridge for each connected LAN

segment. A designated bridge has the lowest path cost to the root bridge among the

bridges connected to the LAN segment. All the ports on a root bridge (root switch) are

designated ports.

•Alternate - A blocked port, which has a best alternate path to the root bridge. This path is

different from using the root port. The port moves to the forwarding state when the

designated port for the LAN segment fails.

•Backup - A blocked port, which has a backup/redundant path to a LAN segment where

a designated port is already connected when a switch has two links to the same LAN

segment.

•Disabled - Not strictly part of STP. The port can be disabled manually.

Designated Bridge

This field displays the identifier of the designated bridge to which this port belongs when the

port is a designated port. Otherwise, it displays the identifier of the designated bridge for the

LAN segment to which this port is connected.

Designated Port ID This field displays the priority and number of the bridge port (on the designated bridge),

through which the designated bridge transmits the stored configuration messages.

Table 56 Advanced Application > Spanning Tree Protocol > Status: MSTP (continued)

LABEL DESCRIPTION

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13.8 Configure Multiple Rapid Spanning Tree Protocol

To configure MRSTP, click MRSTP in the Advanced Application > Spanning Tree Protocol screen. See

Section 13.1 on page 138 for more information on MRSTP.

Figure 120 Advanced Application > Spanning Tree Protocol > MRSTP

The following table describes the labels in this screen.

Designated Cost This field displays the path cost to the LAN segment to which the port is connected when the

port is a designated port. Otherwise, it displays the path cost to the root bridge from the

designated port for the LAN segment to which this port is connected.

Root Guard State This field displays the state of the port on which root guard is enabled.

•Root-inconsistent - the Switch receives superior BPDUs on the port and blocks the port.

•Forwarding - the Switch unblocks and allows the port to forward frames again.

Table 56 Advanced Application > Spanning Tree Protocol > Status: MSTP (continued)

LABEL DESCRIPTION

Table 57 Advanced Application > Spanning Tree Protocol > MRSTP

LABEL DESCRIPTION

Status Click Status to display the MRSTP Status screen (see Figure 121 on page 155).

Tree This is a read only index number of the STP trees.

Active Select this check box to activate an STP tree. Clear this check box to disable an STP tree.

Note: You must also activate Multiple Rapid Spanning Tree in the Advanced

Application > Spanning Tree Protocol > Configuration screen to enable MRSTP

on the Switch.

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Bridge Priority Bridge priority is used in determining the root switch, root port and designated port. The switch

with the highest priority (lowest numeric value) becomes the STP root switch. If all switches

have the same priority, the switch with the lowest MAC address will then become the root

switch. Select a value from the drop-down list box.

The lower the numeric value you assign, the higher the priority for this bridge.

Bridge Priority determines the root bridge, which in turn determines Hello Time, Max Age and

Forwarding Delay.

Hello Time This is the time interval in seconds between BPDU (Bridge Protocol Data Units) configuration

message generations by the root switch. The allowed range is 1 to 10 seconds.

Max Age This is the maximum time (in seconds) the Switch can wait without receiving a BPDU before

attempting to reconfigure. All Switch ports (except for designated ports) should receive BPDUs

at regular intervals. Any port that ages out STP information (provided in the last BPDU)

becomes the designated port for the attached LAN. If it is a root port, a new root port is

selected from among the Switch ports attached to the network. The allowed range is 6 to 40

seconds.

Forwarding Delay This is the maximum time (in seconds) the Switch will wait before changing states. This delay is

required because every switch must receive information about topology changes before it

starts to forward frames. In addition, each port needs time to listen for conflicting information

that would make it return to a blocking state; otherwise, temporary data loops might result.

The allowed range is 4 to 30 seconds.

As a general rule:

Note: 2 * (Forward Delay - 1) >= Max Age >= 2 * (Hello Time + 1)

Port This field displays the port number.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select this check box to activate STP on this port.

Edge Select this check box to configure a port as an edge port when it is directly attached to a

computer. An edge port changes its initial STP port state from blocking state to forwarding

state immediately without going through listening and learning states right after the port is

configured as an edge port or when its link status changes.

Note: An edge port becomes a non-edge port as soon as it receives a Bridge

Protocol Data Unit (BPDU).

Root Guard Select this check box to enable root guard on this port in order to prevent the switch(es)

attached to the port from becoming the root bridge.

With root guard enabled, a port is blocked when the Switch receives a superior BPDU on it. The

Switch allows traffic to pass through this port again when the switch connected to the port

stops to send superior BPDUs.

Priority Configure the priority for each port here.

Priority decides which port should be disabled when more than one port forms a loop in a

switch. Ports with a higher priority numeric value are disabled first. The allowed range is

between 0 and 255 and the default value is 128.

Path Cost Path cost is the cost of transmitting a frame on to a LAN through that port. It is recommended

to assign this value according to the speed of the bridge. The slower the media, the higher the

cost - see Table 49 on page 139 for more information.

Tree Select which STP tree configuration this port should participate in.

Table 57 Advanced Application > Spanning Tree Protocol > MRSTP (continued)

LABEL DESCRIPTION

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13.9 Multiple Rapid Spanning Tree Protocol Status

Click Advanced Application > Spanning Tree Protocol in the navigation panel to display the status

screen as shown next. See Section 13.1 on page 138 for more information on MRSTP.

Note: This screen is only available after you activate MRSTP on the Switch.

Figure 121 Advanced Application > Spanning Tree Protocol > Status: MRSTP

The following table describes the labels in this screen.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 57 Advanced Application > Spanning Tree Protocol > MRSTP (continued)

LABEL DESCRIPTION

Table 58 Advanced Application > Spanning Tree Protocol > Status: MRSTP

LABEL DESCRIPTION

Configuration Click Configuration to specify which STP mode you want to activate. Click MRSTP to edit

MRSTP settings on the Switch.

Tree Select which STP tree configuration you want to view.

Bridge Root refers to the base of the spanning tree (the root bridge). Our Bridge is this switch. This

Switch may also be the root bridge.

Bridge ID This is the unique identifier for this bridge, consisting of bridge priority plus MAC address. This ID

is the same for Root and Our Bridge if the Switch is the root switch.

Hello Time

(second)

This is the time interval (in seconds) at which the root switch transmits a configuration

message. The root bridge determines Hello Time, Max Age and Forwarding Delay.

Max Age (second) This is the maximum time (in seconds) the Switch can wait without receiving a configuration

message before attempting to reconfigure.

Forwarding Delay

(second)

This is the time (in seconds) the root switch will wait before changing states (that is, listening to

learning to forwarding).

Note: The listening state does not exist in RSTP.

Cost to Bridge This is the path cost from the root port on this Switch to the root switch.

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13.10 Technical Reference

This section provides technical background information on the topics discussed in this chapter.

13.10.1 MSTP Network Example

The following figure shows a network example where two VLANs are configured on the two switches. If

the switches are using STP or RSTP, the link for VLAN 2 will be blocked as STP and RSTP allow only one link

in the network and block the redundant link.

Port ID This is the priority and number of the port on the Switch through which this Switch must

communicate with the root of the Spanning Tree.

Topology

Changed Times

This is the number of times the spanning tree has been reconfigured.

Time Since Last

Change

This is the time since the spanning tree was last reconfigured.

Port This field displays the number of the port on the Switch.

Port State This field displays the port state in STP.

•Discarding - The port does not forward/process received frames or learn MAC addresses,

but still listens for BPDUs.

•Learning - The port learns MAC addresses and processes BPDUs, but does not forward

frames yet.

•Forwarding - The port is operating normally. It learns MAC addresses, processes BPDUs and

forwards received frames.

Port Role This field displays the role of the port in STP.

•Root - A forwarding port on a non-root bridge, which has the lowest path cost and is the

best port from the non-root bridge to the root bridge. A root bridge does not have a root

port.

•Designated - A forwarding port on the designated bridge for each connected LAN

segment. A designated bridge has the lowest path cost to the root bridge among the

bridges connected to the LAN segment. All the ports on a root bridge (root switch) are

designated ports.

•Alternate - A blocked port, which has a best alternate path to the root bridge. This path is

different from using the root port. The port moves to the forwarding state when the

designated port for the LAN segment fails.

•Backup - A blocked port, which has a backup/redundant path to a LAN segment where

a designated port is already connected when a switch has two links to the same LAN

segment.

•Disabled - Not strictly part of STP. The port can be disabled manually.

Designated Bridge

This field displays the identifier of the designated bridge to which this port belongs when the

port is a designated port. Otherwise, it displays the identifier of the designated bridge for the

LAN segment to which this port is connected.

Designated Port ID This field displays the priority and number of the bridge port (on the designated bridge),

through which the designated bridge transmits the stored configuration messages.

Designated Cost This field displays the path cost to the LAN segment to which the port is connected when the

port is a designated port. Otherwise, it displays the path cost to the root bridge from the

designated port for the LAN segment to which this port is connected,

Table 58 Advanced Application > Spanning Tree Protocol > Status: MRSTP (continued)

LABEL DESCRIPTION

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Figure 122 STP/RSTP Network Example

With MSTP, VLANs 1 and 2 are mapped to different spanning trees in the network. Thus traffic from the

two VLANs travel on different paths. The following figure shows the network example using MSTP.

Figure 123 MSTP Network Example

13.10.2 MST Region

An MST region is a logical grouping of multiple network devices that appears as a single device to the

rest of the network. Each MSTP-enabled device can only belong to one MST region. When BPDUs enter

an MST region, external path cost (of paths outside this region) is increased by one. Internal path cost (of

paths within this region) is increased by one when BPDUs traverse the region.

Devices that belong to the same MST region are configured to have the same MSTP configuration

identification settings. These include the following parameters:

• Name of the MST region

• Revision level as the unique number for the MST region

• VLAN-to-MST Instance mapping

13.10.3 MST Instance

An MST Instance (MSTI) is a spanning tree instance. VLANs can be configured to run on a specific MSTI.

Each created MSTI is identified by a unique number (known as an MST ID) known internally to a region.

Thus an MSTI does not span across MST regions.

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The following figure shows an example where there are two MST regions. Regions 1 and 2 have 2

spanning tree instances.

Figure 124 MSTIs in Different Regions

13.10.4 Common and Internal Spanning Tree (CIST)

A CIST represents the connectivity of the entire network and it is equivalent to a spanning tree in an STP/

RSTP. The CIST is the default MST instance (MSTID 0). Any VLANs that are not members of an MST instance

are members of the CIST. In an MSTP-enabled network, there is only one CIST that runs between MST

regions and single spanning tree devices. A network may contain multiple MST regions and other

network segments running RSTP.

Figure 125 MSTP and Legacy RSTP Network Example

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CHAPTER 14

Bandwidth Control

14.1 Bandwidth Control Overview

This chapter shows you how you can cap the maximum bandwidth using the Bandwidth Control screen.

Bandwidth control means defining a maximum allowable bandwidth for incoming and/or out-going

traffic flows on a port.

14.1.1 What You Can Do

Use the Bandwidth Control screen (Section 14.2 on page 159) to limit the bandwidth for traffic going

through the Switch.

14.2 Bandwidth Control Setup

Click Advanced Application > Bandwidth Control in the navigation panel to bring up the screen as

shown next.

Figure 126 Advanced Application > Bandwidth Control

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The following table describes the related labels in this screen.

Table 59 Advanced Application > Bandwidth Control

LABEL DESCRIPTION

Active Select this check box to enable bandwidth control on the Switch.

Port This field displays the port number. * means all ports.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set the

common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select this check box to activate ingress rate limits on this port.

Ingress Rate Specify the maximum bandwidth allowed in kilobits per second (Kbps) for the incoming traffic flow

on a port.

Note: Ingress rate bandwidth control applies to layer 2 traffic only.

Active Select this check box to activate egress rate limits on this port.

Egress Rate Specify the maximum bandwidth allowed in kilobits per second (Kbps) for the out-going traffic

flow on a port.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these changes

if it is turned off or loses power, so use the Save link on the top navigation panel to save your

changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields.

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CHAPTER 15

Broadcast Storm Control

15.1 Broadcast Storm Control Overview

This chapter introduces and shows you how to configure the broadcast storm control feature.

Broadcast storm control limits the number of broadcast, multicast and destination lookup failure (DLF)

packets the Switch receives per second on the ports. When the maximum number of allowable

broadcast, multicast and/or DLF packets is reached per second, the subsequent packets are

discarded. Enable this feature to reduce broadcast, multicast and/or DLF packets in your network. You

can specify limits for each packet type on each port.

15.1.1 What You Can Do

Use the Broadcast Storm Control screen (Section 15.2 on page 161) to limit the number of broadcast,

multicast and destination lookup failure (DLF) packets the Switch receives per second on the ports.

15.2 Broadcast Storm Control Setup

Click Advanced Application > Broadcast Storm Control in the navigation panel to display the screen as

shown next.

Figure 127 Advanced Application > Broadcast Storm Control

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The following table describes the labels in this screen.

Table 60 Advanced Application > Broadcast Storm Control

LABEL DESCRIPTION

Active Select this check box to enable traffic storm control on the Switch. Clear this check box to

disable this feature.

Port This field displays the port number. * means all ports.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Broadcast (pkt/s) Select this option and specify how many broadcast packets the port receives per second.

Multicast (pkt/s) Select this option and specify how many multicast packets the port receives per second.

DLF (pkt/s) Select this option and specify how many destination lookup failure (DLF) packets the port

receives per second.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields.

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CHAPTER 16

Mirroring

16.1 Mirroring Overview

This chapter discusses port mirroring setup screens.

Port mirroring allows you to copy a traffic flow to a monitor port (the port you copy the traffic to) in order

that you can examine the traffic from the monitor port without interference.

16.1.1 What You Can Do

Use the Mirroring screen (Section 16.2 on page 163) to select a monitor port and specify the traffic flow

to be copied to the monitor port.

16.2 Port Mirroring Setup

Click Advanced Application > Mirroring in the navigation panel to display the Mirroring screen. Use this

screen to select a monitor port and specify the traffic flow to be copied to the monitor port.

Figure 128 Advanced Application > Mirroring

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The following table describes the labels in this screen.

Table 61 Advanced Application > Mirroring

LABEL DESCRIPTION

Active Select this check box to activate port mirroring on the Switch. Clear this check box to disable the

feature.

Monitor Port The monitor port is the port you copy the traffic to in order to examine it in more detail without

interfering with the traffic flow on the original port(s). Enter the port number of the monitor port.

Port This field displays the port number. * means all ports.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set the

common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Mirrored Select this option to mirror the traffic on a port.

Direction Specify the direction of the traffic to mirror by selecting from the drop-down list box. Choices are

Egress (outgoing), Ingress (incoming) and Both.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these changes

if it is turned off or loses power, so use the Save link on the top navigation panel to save your

changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields.

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CHAPTER 17

Link Aggregation

17.1 Link Aggregation Overview

This chapter shows you how to logically aggregate physical links to form one logical, higher-bandwidth

link.

Link aggregation (trunking) is the grouping of physical ports into one logical higher-capacity link. You

may want to trunk ports if for example, it is cheaper to use multiple lower-speed links than to under-utilize

a high-speed, but more costly, single-port link. However, the more ports you aggregate then the fewer

available ports you have. A trunk group is one logical link containing multiple ports.

The beginning port of each trunk group must be physically connected to form a trunk group.

17.1.1 What You Can Do

• Use the Link Aggregation Status screen (Section 17.2 on page 166) to view ports you have configured

to be in the trunk group, ports that are currently transmitting data as one logical link in the trunk group

and so on.

• Use the Link Aggregation Setting screen (Section 17.3 on page 167) to configure to enable static link

aggregation.

• Use the Link Aggregation Control Protocol screen (Section 17.3.1 on page 169) to enable Link

Aggregation Control Protocol (LACP).

17.1.2 What You Need to Know

The Switch supports both static and dynamic link aggregation.

Note: In a properly planned network, it is recommended to implement static link aggregation

only. This ensures increased network stability and control over the trunk groups on your

Switch.

See Section 17.4.1 on page 170 for a static port trunking example.

Dynamic Link Aggregation

The Switch adheres to the IEEE 802.3ad standard for static and dynamic (LACP) port trunking.

The IEEE 802.3ad standard describes the Link Aggregation Control Protocol (LACP) for dynamically

creating and managing trunk groups.

When you enable LACP link aggregation on a port, the port can automatically negotiate with the ports

at the remote end of a link to establish trunk groups. LACP also allows port redundancy, that is, if an

operational port fails, then one of the “standby” ports become operational without user intervention.

Please note that:

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• You must connect all ports point-to-point to the same Ethernet switch and configure the ports for

LACP trunking.

• LACP only works on full-duplex links.

• All ports in the same trunk group must have the same media type, speed, duplex mode and flow

control settings.

Configure trunk groups or LACP before you connect the Ethernet switch to avoid causing network

topology loops.

Link Aggregation ID

LACP aggregation ID consists of the following information1:

17.2 Link Aggregation Status

Click Advanced Application > Link Aggregation in the navigation panel. The Link Aggregation Status

screen displays by default. See Section 17.1 on page 165 for more information.

Figure 129 Advanced Application > Link Aggregation

Table 62 Link Aggregation ID: Local Switch

SYSTEM PRIORITY MAC ADDRESS KEY PORT PRIORITY PORT NUMBER

0000 00-00-00-00-00-00 0000 00 0000

Table 63 Link Aggregation ID: Peer Switch

SYSTEM PRIORITY MAC ADDRESS KEY PORT PRIORITY PORT NUMBER

0000 00-00-00-00-00-00 0000 00 0000

1. Port Priority and Port Number are 0 as it is the aggregator ID for the trunk group, not the individual port.

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The following table describes the labels in this screen.

17.3 Link Aggregation Setting

Click Advanced Application > Link Aggregation > Link Aggregation Setting to display the screen shown

next. See Section 17.1 on page 165 for more information on link aggregation.

Table 64 Advanced Application > Link Aggregation

LABEL DESCRIPTION

Group ID This field displays the group ID to identify a trunk group, that is, one logical link containing multiple

ports.

Enabled Ports These are the ports you have configured in the Link Aggregation screen to be in the trunk group.

The port number(s) displays only when this trunk group is activated and there is a port belonging

to this group.

Synchronized

Ports

These are the ports that are currently transmitting data as one logical link in this trunk group.

Aggregator ID Link Aggregator ID consists of the following: system priority, MAC address, key, port priority and

port number. Refer to Link Aggregation ID on page 166 for more information on this field.

The ID displays only when there is a port belonging to this trunk group and LACP is also enabled

for this group.

Criteria This shows the outgoing traffic distribution algorithm used in this trunk group. Packets from the

same source and/or to the same destination are sent over the same link within the trunk.

src-mac means the Switch distributes traffic based on the packet’s source MAC address.

dst-mac means the Switch distributes traffic based on the packet’s destination MAC address.

src-dst-mac means the Switch distributes traffic based on a combination of the packet’s source

and destination MAC addresses.

src-ip means the Switch distributes traffic based on the packet’s source IP address.

dst-ip means the Switch distributes traffic based on the packet’s destination IP address.

src-dst-ip means the Switch distributes traffic based on a combination of the packet’s source

and destination IP addresses.

Status This field displays how these ports were added to the trunk group. It displays:

•Static - if the ports are configured as static members of a trunk group.

•LACP - if the ports are configured to join a trunk group via LACP.

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Figure 130 Advanced Application > Link Aggregation > Link Aggregation Setting

The following table describes the labels in this screen.

Table 65 Advanced Application > Link Aggregation > Link Aggregation Setting

LABEL DESCRIPTION

Link

Aggregation

Setting

This is the only screen you need to configure to enable static link aggregation.

Group ID The field identifies the link aggregation group, that is, one logical link containing multiple ports.

Active Select this option to activate a trunk group.

Criteria Select the outgoing traffic distribution type. Packets from the same source and/or to the same

destination are sent over the same link within the trunk. By default, the Switch uses the src-dst-mac

distribution type. If the Switch is behind a router, the packet’s destination or source MAC address

will be changed. In this case, set the Switch to distribute traffic based on its IP address to make

sure port trunking can work properly.

Select src-mac to distribute traffic based on the packet’s source MAC address.

Select dst-mac to distribute traffic based on the packet’s destination MAC address.

Select src-dst-mac to distribute traffic based on a combination of the packet’s source and

destination MAC addresses.

Select src-ip to distribute traffic based on the packet’s source IP address.

Select dst-ip to distribute traffic based on the packet’s destination IP address.

Select src-dst-ip to distribute traffic based on a combination of the packet’s source and

destination IP addresses.

Port This field displays the port number.

Group Select the trunk group to which a port belongs.

Note: When you enable the port security feature on the Switch and configure port

security settings for a port, you cannot include the port in an active trunk group.

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17.3.1 Link Aggregation Control Protocol

Click Advanced Application > Link Aggregation > Link Aggregation Setting > LAC P to display the screen

shown next. See Dynamic Link Aggregation on page 165 for more information on dynamic link

aggregation.

Figure 131 Advanced Application > Link Aggregation > Link Aggregation Setting > LACP

The following table describes the labels in this screen.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 65 Advanced Application > Link Aggregation > Link Aggregation Setting (continued)

LABEL DESCRIPTION

Table 66 Advanced Application > Link Aggregation > Link Aggregation Setting > LACP

LABEL DESCRIPTION

Link

Aggregation

Control

Protocol

Note: Do not configure this screen unless you want to enable dynamic link

aggregation.

Active Select this check box to enable Link Aggregation Control Protocol (LACP).

System Priority LACP system priority is a number between 1 and 65,535. The switch with the lowest system priority

(and lowest port number if system priority is the same) becomes the LACP “server”. The LACP

“server” controls the operation of LACP setup. Enter a number to set the priority of an active port

using Link Aggregation Control Protocol (LACP). The smaller the number, the higher the priority

level.

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17.4 Technical Reference

This section provides technical background information on the topics discussed in this chapter.

17.4.1 Static Trunking Example

This example shows you how to create a static port trunk group for ports 2-5.

1Make your physical connections - make sure that the ports that you want to belong to the trunk group

are connected to the same destination. The following figure shows ports 2-5 on switch A connected to

switch B.

Figure 132 Trunking Example - Physical Connections

2Configure static trunking - Click Advanced Application > Link Aggreg ation > Link Aggregation Setting. In

this screen activate trunk group T1, select the traffic distribution algorithm used by this group and select

the ports that should belong to this group as shown in the figure below. Click Apply when you are done.

Group ID The field identifies the link aggregation group, that is, one logical link containing multiple ports.

LACP Active Select this option to enable LACP for a trunk.

Port This field displays the port number. * means all ports.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

LACP Timeout Timeout is the time interval between the individual port exchanges of LACP packets in order to

check that the peer port in the trunk group is still up. If a port does not respond after three tries,

then it is deemed to be “down” and is removed from the trunk. Set a short timeout (one second)

for busy trunked links to ensure that disabled ports are removed from the trunk group as soon as

possible.

Select either 1 second or 30 seconds.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 66 Advanced Application > Link Aggregation > Link Aggregation Setting > LACP (continued)

LABEL DESCRIPTION

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Figure 133 Trunking Example - Configuration Screen

Your trunk group 1 (T1) configuration is now complete.

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CHAPTER 18

Port Authentication

18.1 Port Authentication Overview

This chapter describes the IEEE 802.1x and MAC authentication methods.

Port authentication is a way to validate access to ports on the Switch to clients based on an external

server (authentication server). The Switch supports the following methods for port authentication:

•IEEE 802.1x2 - An authentication server validates access to a port based on a username and

password provided by the user.

•MAC Authentication - An authentication server validates access to a port based on the MAC address

and password of the client.

Both types of authentication use the RADIUS (Remote Authentication Dial In User Service, RFC 2138,

2139) protocol to validate users. See RADIUS and TACACS+ on page 225 for more information on

configuring your RADIUS server settings.

Note: If you enable IEEE 802.1x authentication and MAC authentication on the same port, the

Switch performs IEEE 802.1x authentication first. If a user fails to authenticate via the IEEE

802.1x method, then access to the port is denied.

18.1.1 What You Can Do

• Use the Port Authentication screen (Section 18.2 on page 174) to display the links to the configuration

screens where you can enable the port authentication methods.

• Use the 802.1x screen (Section 18.3 on page 174) to activate IEEE 802.1x security.

• Use the MAC Authentication screen (Section 18.4 on page 178) to activate MAC authentication.

18.1.2 What You Need to Know

IEEE 802.1x Authentication

The following figure illustrates how a client connecting to a IEEE 802.1x authentication enabled port goes

through a validation process. The Switch prompts the client for login information in the form of a user

name and password. When the client provides the login credentials, the Switch sends an authentication

request to a RADIUS server. The RADIUS server validates whether this client is allowed access to the port.

2. At the time of writing, IEEE 802.1x is not supported by all operating systems. See your operating system

documentation. If your operating system does not support 802.1x, then you may need to install 802.1x client

software.

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Figure 134 IEEE 802.1x Authentication Process

18.1.3 MAC Authentication

MAC authentication works in a very similar way to IEEE 802.1x authentication. The main difference is that

the Switch does not prompt the client for login credentials. The login credentials are based on the

source MAC address of the client connecting to a port on the Switch along with a password configured

specifically for MAC authentication on the Switch.

Figure 135 MAC Authentication Process

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18.2 Port Authentication Configuration

To enable port authentication, first activate the port authentication method(s) (both on the Switch and

the port(s)), then configure the RADIUS server settings in the AAA > RADIUS Server Setup screen.

Click Advanced Application > Port Authentication in the navigation panel to display the screen as

shown. Select a port authentication method’s link in the screen that appears.

Figure 136 Advanced Application > Port Authentication

18.3 Activate IEEE 802.1x Security

Use this screen to activate IEEE 802.1x security. In the Port Authentication screen click 802.1x to display

the configuration screen as shown.

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Figure 137 Advanced Application > Port Authentication > 802.1x

The following table describes the labels in this screen.

Table 67 Advanced Application > Port Authentication > 802.1x

LABEL DESCRIPTION

Active Select this check box to permit 802.1x authentication on the Switch.

Note: You must first enable 802.1x authentication on the Switch before configuring it

on each port.

EAPOL flood Select this check box to flood EAPoL packets to all ports in the same VLAN.

EAP over LAN (EAPOL) is a port authentication protocol used in IEEE 802.1x. It is used to

encapsulate and transmit EAP packets between the supplicant (a client device that requests

access to the network resources or services) and authenticator (the Switch) directly over the

LAN.

Note: EAPOL flood will not take effect when 802.1x authentication is enabled.

Port This field displays the port number. * means all ports.

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18.3.1 Guest VLAN

When 802.1x port authentication is enabled on the Switch and its ports, clients that do not have the

correct credentials are blocked from using the port(s). You can configure your Switch to have one VLAN

that acts as a guest VLAN. If you enable the guest VLAN (102 in the example) on a port (2 in the

example), the user (A in the example) that is not IEEE 802.1x capable or fails to enter the correct

username and password can still access the port, but traffic from the user is forwarded to the guest

VLAN. That is, unauthenticated users can have access to limited network resources in the same guest

VLAN, such as the Internet. The rights granted to the Guest VLAN depends on how the network

administrator configures switches or routers with the guest network feature.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select this to permit 802.1x authentication on this port. You must first allow 802.1x

authentication on the Switch before configuring it on each port.

Max-Req Specify the number of times the Switch tries to authenticate client(s) before sending

unresponsive ports to the Guest VLAN.

This is set to 2 by default. That is, the Switch attempts to authenticate a client twice. If the client

does not respond to the first authentication request, the Switch tries again. If the client still does

not respond to the second request, the Switch sends the client to the Guest VLAN. The client

needs to send a new request to be authenticated by the Switch again.

Reauth Specify if a subscriber has to periodically re-enter his or her username and password to stay

connected to the port.

Reauth-period

secs

Specify the length of time required to pass before a client has to re-enter his or her username

and password to stay connected to the port.

Quiet-period secs Specify the number of seconds the port remains in the HELD state and rejects further

authentication requests from the connected client after a failed authentication exchange.

Tx-period secs Specify the number of seconds the Switch waits for client’s response before re-sending an

identity request to the client.

Supp-Timeout

secs

Specify the number of seconds the Switch waits for client’s response to a challenge request

before sending another request.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 67 Advanced Application > Port Authentication > 802.1x (continued)

LABEL DESCRIPTION

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Figure 138 Guest VLAN Example

Use this screen to enable and assign a guest VLAN to a port. In the Port Authentication > 802.1x screen

click Guest Vlan to display the configuration screen as shown.

Figure 139 Advanced Application > Port Authentication > 802.1x > Guest VLAN

The following table describes the labels in this screen.

Table 68 Advanced Application > Port Authentication > 802.1x > Guest VLAN

LABEL DESCRIPTION

Port This field displays a port number. * means all ports.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Changes in this row are copied to all the ports as soon as you make them.

Active Select this check box to enable the guest VLAN feature on this port.

Clients that fail authentication are placed in the guest VLAN and can receive limited services.

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18.4 Activate MAC Authentication

Use this screen to activate MAC authentication. In the Port Authentication screen click MAC

Authentication to display the configuration screen as shown.

Guest Vlan A guest VLAN is a pre-configured VLAN on the Switch that allows non-authenticated users to

access limited network resources through the Switch. You must also enable IEEE 802.1x

authentication on the Switch and the associated ports. Enter the number that identifies the

guest VLAN.

Make sure this is a VLAN recognized in your network.

Host-mode Specify how the Switch authenticates users when more than one user connect to the port

(using a hub).

Select Multi-Host to authenticate only the first user that connects to this port. If the first user

enters the correct credential, any other users are allowed to access the port without

authentication. If the first user fails to enter the correct credential, they are all put in the guest

VLAN. Once the first user who did authentication logs out or disconnects from the port, rest of

the users are blocked until a user does the authentication process again.

Select Multi-Secure to authenticate each user that connects to this port.

Multi-Secure Num If you set Host-mode to Multi-Secure, specify the maximum number of users that the Switch will

authenticate on this port.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 68 Advanced Application > Port Authentication > 802.1x > Guest VLAN (continued)

LABEL DESCRIPTION

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Figure 140 Advanced Application > Port Authentication > MAC Authentication

The following table describes the labels in this screen.

Table 69 Advanced Application > Port Authentication > MAC Authentication

LABEL DESCRIPTION

Active Select this check box to permit MAC authentication on the Switch.

Note: You must first enable MAC authentication on the Switch before configuring it

on each port.

Name Prefix Type the prefix that is appended to all MAC addresses sent to the RADIUS server for

authentication. You can enter up to 32 printable ASCII characters.

If you leave this field blank, then only the MAC address of the client is forwarded to the RADIUS

server.

Delimiter Select the delimiter the RADIUS server uses to separate the pairs in MAC addresses used as the

account username (and password). You can select Dash (-), Colon (:), or None to use no

delimiters at all in the MAC address.

Case Select the case (Upper or Lower) the RADIUS server requires for letters in MAC addresses used

as the account username (and password).

Password Type Select Static to have the Switch send the password you specify below or MAC-Address to use

the client MAC address as the password.

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Password Type the password the Switch sends along with the MAC address of a client for authentication

with the RADIUS server. You can enter up to 32 printable ASCII characters.

Timeout Specify the amount of time before the Switch allows a client MAC address that fails

authentication to try and authenticate again. Maximum time is 3000 seconds.

When a client fails MAC authentication, its MAC address is learned by the MAC address table

with a status of denied. The timeout period you specify here is the time the MAC address entry

stays in the MAC address table until it is cleared. If you specify 0 for the timeout value, the

Switch uses the Aging Time configured in the Switch Setup screen.

Note: If the Aging Time in the Switch Setup screen is set to a lower value, then it

supersedes this setting. See Section 8.5 on page 85.

Port This field displays a port number. * means all ports.

* Use this row to make the setting the same for all ports. Use this row first and then make

adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select this check box to permit MAC authentication on this port. You must first allow MAC

authentication on the Switch before configuring it on each port.

Trusted VLAN List Enter the ID number(s) of the trusted VLAN(s) (separated by a comma). If a client’s VLAN ID is

specified here, the client can access the port and the connected networks without MAC

authentication.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 69 Advanced Application > Port Authentication > MAC Authentication (continued)

LABEL DESCRIPTION

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CHAPTER 19

Port Security

19.1 Port Security Overview

This chapter shows you how to set up port security.

Port security allows only packets with dynamically learned MAC addresses and/or configured static

MAC addresses to pass through a port on the Switch. The Switch can learn up to 16K MAC addresses in

total with no limit on individual ports other than the sum cannot exceed 16K.

For maximum port security, enable this feature, disable MAC address learning and configure static MAC

address(es) for a port. It is not recommended you disable port security together with MAC address

learning as this will result in many broadcasts. By default, MAC address learning is still enabled even

though the port security is not activated.

19.1.1 What You Can Do

Use the Port Security screen (Section 19.2 on page 181) to enable port security and disable MAC

address learning. You can also enable the port security feature on a port.

19.2 Port Security Setup

Click Advanced Application > Port Security in the navigation panel to display the screen as shown.

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Figure 141 Advanced Application > Port Security

The following table describes the labels in this screen.

Table 70 Advanced Application > Port Security

LABEL DESCRIPTION

Port Security

Active Select this option to enable port security on the Switch.

Port This field displays the port number. * means all ports.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select this check box to enable the port security feature on this port. The Switch forwards

packets whose MAC address(es) is in the MAC address table on this port. Packets with no

matching MAC address(es) are dropped.

Clear this check box to disable the port security feature. The Switch forwards all packets on this

port.

Address

Learning

MAC address learning reduces outgoing broadcast traffic. For MAC address learning to occur

on a port, the port itself must be active with address learning enabled.

Limited Number

of Learned MAC

Address

Use this field to limit the number of (dynamic) MAC addresses that may be learned on a port. For

example, if you set this field to "5" on port 2, then only the devices with these five learned MAC

addresses may access port 2 at any one time. A sixth device would have to wait until one of the

five learned MAC addresses aged out. MAC address aging out time can be set in the Switch

Setup screen. The valid range is from “0” to “16K”. “0” means this feature is disabled.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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CHAPTER 20

Time Range

You can set up one-time and recurring schedules for time-oriented features, such as PoE and classifier.

The UAG supports one-time and recurring schedules. One-time schedules are effective only once, while

recurring schedules usually repeat. Both types of schedules are based on the current date and time in

the Switch.

20.1.1 What You Can Do

Use the Time Range screen (Section 20.2 on page 183) to view or define a schedule on the Switch.

20.2 Configuring Time Range

Click Advanced Application > Time Range in the navigation panel to display the screen as shown.

Figure 142 Advanced Application > Time Range

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The following table describes the labels in this screen.

Table 71 Advanced Application > Time Range

LABEL DESCRIPTION

Name Enter a descriptive name for this rule for identifying purposes.

Type Select Absolute to create a one-time schedule. One-time schedules begin on a specific start

date and time and end on a specific stop date and time. One-time schedules are useful for

long holidays and vacation periods.

Alternatively, select Periodic to create a recurring schedule. Recurring schedules begin at a

specific start time and end at a specific stop time on selected days of the week (Sunday,

Monday, Tuesday, Wednesday, Thursday, Friday, and Saturday). Recurring schedules are useful

for defining the workday and off-work hours.

Absolute This section is available only when you set Type to Absolute.

Start Specify the year, month, day, hour and minute when the schedule begins.

End Specify the year, month, day, hour and minute when the schedule ends.

Periodic This section is available only when you set Type to Periodic.

Select the first option if you want to define a recurring schedule for a consecutive time period.

You then select the day of the week, hour and minute when the schedule begins and ends

respectively.

Select the second option if you want to define a recurring schedule for multiple non-

consecutive time periods. You need to select each day of the week the recurring schedule is

effective. You also need to specify the hour and minute when the schedule begins and ends

each day. The schedule begins and ends in the same day.

Add Click Add to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to your previous configuration.

Clear Click Clear to clear the fields to the factory defaults.

Index This field displays the index number of the rule. Click an index number to change the settings.

Name This field displays the descriptive name for this rule. This is for identification purpose only.

Type This field displays the type of the schedule.

Range This field displays the time period(s) to which this schedule applies.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Check the rule(s) that you want to remove and then click the Delete button.

Cancel Click Cancel to clear the selected checkbox(es).

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CHAPTER 21

Classifier

21.1 Classifier Overview

This chapter introduces and shows you how to configure the packet classifier on the Switch. It also

discusses Quality of Service (QoS) and classifier concepts as employed by the Switch.

21.1.1 What You Can Do

• Use the Classifier Status screen (Section 21.2 on page 185) to view the classifiers configured on the

Switch and how many times the traffic matches the rules.

• Use the Classifier Configuration screen (Section 21.3 on page 186) to define the classifiers and view a

summary of the classifier configuration. After you define the classifier, you can specify actions (or

policy) to act upon the traffic that matches the rules.

• Use the Classifier Global Setting screen (Section 21.4 on page 191) to configure the match order and

enable logging on the Switch.

21.1.2 What You Need to Know

Quality of Service (QoS) refers to both a network's ability to deliver data with minimum delay, and the

networking methods used to control the use of bandwidth. Without QoS, all traffic data is equally likely

to be dropped when the network is congested. This can cause a reduction in network performance and

make the network inadequate for time-critical application such as video-on-demand.

A classifier groups traffic into data flows according to specific criteria such as the source address,

destination address, source port number, destination port number or incoming port number. For

example, you can configure a classifier to select traffic from the same protocol port (such as Telnet) to

form a flow.

Configure QoS on the Switch to group and prioritize application traffic and fine-tune network

performance. Setting up QoS involves two separate steps:

1Configure classifiers to sort traffic into different flows.

2Configure policy rules to define actions to be performed on a classified traffic flow (refer to Chapter 22

on page 194 to configure policy rules).

21.2 Classifier Status

Use this screen to view the classifiers configured on the Switch and how many times the traffic matches

the rules.

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Click Advanced Application > Classifier in the navigation panel to display the configuration screen as

shown.

Figure 143 Advanced Application > Classifier

The following table describes the labels in this screen.

21.3 Classifier Configuration

Use the Classifier Configuration screen to define the classifiers. After you define the classifier, you can

specify actions (or policy) to act upon the traffic that matches the rules. To configure policy rules, refer

to Chapter 22 on page 194.

In the Classifier Status screen click Classifier Configuration to display the configuration screen as shown.

Table 72 Advanced Application > Classifier

LABEL DESCRIPTION

Index This field displays the index number of the rule. Click an index number to edit the rule.

Active This field displays Yes when the rule is activated and No when it is deactivated.

Weight This field displays the rule’s weight. This is to indicate a rule’s priority when the match order is set

to manual in the Classifier > Classifier Configuration > Classifier Global Setting screen.

The higher the number, the higher the rule’s priority.

Name This field displays the descriptive name for this rule. This is for identification purpose only.

Match Count This field displays the number of times a rule is applied. It displays '-' if the rule does not have

count enabled.

Rule This field displays a summary of the classifier rule’s settings.

Clear Select Classifier, enter a classifier rule name and then click Clear to erase the recorded

statistical information for the classifier, or select Any to clear statistics for all classifiers.

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Figure 144 Advanced Application > Classifier > Classifier Configuration

The following table describes the labels in this screen.

Table 73 Advanced Application > Classifier > Classifier Configuration

LABEL DESCRIPTION

Active Select this option to enable this rule.

Name Enter a descriptive name for this rule for identifying purposes.

Weight Enter a number between 0 and 65535 to specify the rule’s weight. When the match order is in manual

mode in the Classifier Global Setting screen, a higher weight means a higher priority.

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Log Select this option to have the Switch create a log message when the rule is applied and record the

number of matched packets in a particular time interval.

Note: Make sure you also enable logging in the Classifier Global Setting screen.

Count Select this option to have the Switch count how many times the rule is applied.

Time

Range

Select the name of the pre-configured schedule that you want to apply to the rule. The rule will be

active only at the scheduled date and/or time.

If you select None, the rule will be active all the time.

Ingress Port

Port Type the port number to which the rule should be applied. You may choose one port only or all ports

(Any).

Trunk Select Any to apply the rule to all trunk groups.

To specify a trunk group, select the second choice and type a trunk group ID.

Layer 2

Specify the fields below to configure a layer 2 classifier.

VLAN

VLAN Select Any to classify traffic from any VLAN or select the second option and specify the source VLAN

ID in the field provided.

Priority

Priority Select Any to classify traffic from any priority level or select the second option and specify a priority

level in the field provided.

Ethernet

Type

Select an Ethernet type or select Other and enter the Ethernet type number in hexadecimal value.

Refer to Table 75 on page 190 for information.

Source

MAC

Address

Select Any to apply the rule to all MAC addresses.

To specify a source, select MAC/Mask to enter the source MAC address of the packet in valid MAC

address format (six hexadecimal character pairs) and type the mask for the specified MAC address to

determine which bits a packet’s MAC address should match.

Enter “f” for each bit of the specified MAC address that the traffic’s MAC address should match. Enter

“0” for the bit(s) of the matched traffic’s MAC address, which can be of any hexadecimal

character(s). For example, if you set the MAC address to 00:13:49:00:00:00 and the mask to

ff:ff:ff:00:00:00, a packet with a MAC address of 00:13:49:12:34:56 matches this criteria. If you leave the

Mask field blank, the Switch automatically sets the mask to ff:ff:ff:ff:ff:ff.

Destination

MAC

Address

Select Any to apply the rule to all MAC addresses.

To specify a destination, select MAC/Mask to enter the destination MAC address of the packet in

valid MAC address format (six hexadecimal character pairs) and type the mask for the specified MAC

address to determine which bits a packet’s MAC address should match.

Enter “f” for each bit of the specified MAC address that the traffic’s MAC address should match. Enter

“0” for the bit(s) of the matched traffic’s MAC address, which can be of any hexadecimal

character(s). For example, if you set the MAC address to 00:13:49:00:00:00 and the mask to

ff:ff:ff:00:00:00, a packet with a MAC address of 00:13:49:12:34:56 matches this criteria. If you leave the

Mask field blank, the Switch automatically sets the mask to ff:ff:ff:ff:ff:ff.

Layer 3

Specify the fields below to configure a layer 3 classifier.

Table 73 Advanced Application > Classifier > Classifier Configuration (continued)

LABEL DESCRIPTION

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DSCP

IPv4/IPv6

Select Any to classify traffic from any DSCP or select the second option and specify a DSCP (DiffServ

Code Point) number between 0 and 63 in the field provided.

Preceden

Select Any to classify traffic from any precedence or select the second option and specify an IP

Precedence (the first 3 bits of the 8-bit ToS field) value between 0 and 7 in the field provided.

ToS Select Any to classify traffic from any ToS or select the second option and specify Type of Service (the

last 5 bits of the 8-bit ToS field) value between 0 and 255 in the field provided.

IP Protocol Select an IPv4 protocol type or select Other and enter the protocol number in decimal value. Refer to

Table 76 on page 191 for more information.

You may select Establish Only for TCP protocol type. This means that the Switch will pick out the

packets that are sent to establish TCP connections.

IPv6 Next

Header

Select an IPv6 protocol type or select Other and enter an 8-bit next header in the IPv6 packet. The

Next Header field is similar to the IPv4 Protocol field. The IPv6 protocol number ranges from 1 to 255.

You may select Establish Only for TCP protocol type. This means that the Switch will identify packets

that initiate or acknowledge (establish) TCP connections.

Source

Address/

Address

Prefix

Enter a source IP address in dotted decimal notation.

Specify the address prefix by entering the number of ones in the subnet mask.

A subnet mask can be represented in a 32-bit notation. For example, the subnet mask “255.255.255.0”

can be represented as “11111111.11111111.11111111.00000000”, and counting up the number of

ones in this case results in 24.

Destination

Address/

Address

Prefix

Enter a destination IP address in dotted decimal notation.

Specify the address prefix by entering the number of ones in the subnet mask.

Layer 4

Specify the fields below to configure a layer 4 classifier.

Source

Socket

Number Note: You must select either UDP or TCP in the IP Protocol field before you configure the

socket numbers.

Select Any to apply the rule to all TCP/UDP protocol port numbers or select the second option and

enter a TCP/UDP protocol port number. Refer to Table 77 on page 191 for more information.

Destination

Socket

Number Note: You must select either UDP or TCP in the IP Protocol field before you configure the

socket numbers.

Select Any to apply the rule to all TCP/UDP protocol port numbers or select the second option and

enter a TCP/UDP protocol port number. Refer to Table 77 on page 191 for more information.

Add Click Add to insert the entry in the summary table below and save your changes to the Switch’s run-

time memory. The Switch loses these changes if it is turned off or loses power, so use the Save link on

the top navigation panel to save your changes to the non-volatile memory when you are done

configuring.

Cancel Click Cancel to reset the fields back to your previous configuration.

Clear Click Clear to set the above fields back to the factory defaults.

Table 73 Advanced Application > Classifier > Classifier Configuration (continued)

LABEL DESCRIPTION

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21.3.1 Viewing and Editing Classifier Configuration Summary

To view a summary of the classifier configuration, scroll down to the summary table at the bottom of the

Classifier screen. To change the settings of a rule, click a number in the Index field.

Note: When two rules conflict with each other, a higher layer rule has priority over lower layer

rule.

Figure 145 Advanced Application > Classifier > Classifier Configuration: Summary Table

The following table describes the labels in this screen.

The following table shows some other common Ethernet types and the corresponding protocol number.

Table 74 Advanced Application > Classifier > Classifier Configuration: Summary Table

LABEL DESCRIPTION

Index This field displays the index number of the rule. Click an index number to edit the rule.

Active This field displays Yes when the rule is activated and No when it is deactivated.

Weight The field displays the priority of the rule when the match order is in manual mode. A higher weight

means a higher priority.

Name This field displays the descriptive name for this rule. This is for identification purpose only.

Rule This field displays a summary of the classifier rule’s settings.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the table

heading row to select all entries.

Delete Click Delete to remove the selected entry from the summary table.

Cancel Click Cancel to clear the check boxes.

Table 75 Common Ethernet Types and Protocol Numbers

ETHERNET TYPE PROTOCOL NUMBER

IP ETHII 0800

X.75 Internet 0801

NBS Internet 0802

ECMA Internet 0803

Chaosnet 0804

X.25 Level 3 0805

XNS Compat 0807

Banyan Systems 0BAD

BBN Simnet 5208

IBM SNA 80D5

AppleTalk AARP 80F3

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In the Internet Protocol there is a field, called “Protocol”, to identify the next level protocol. The following

table shows some common protocol types and the corresponding protocol number. Refer to http://

www.iana.org/assignments/protocol-numbers for a complete list.

Some of the most common TCP and UDP port numbers are:

See Appendix B on page 433 for information on commonly used port numbers.

21.4 Classifier Global Setting Configuration

Use this screen to configure the match order and enable logging on the Switch. In the Classifier

Configuration screen click Classifier Global Setting to display the configuration screen as shown.

Figure 146 Advanced Application > Classifier > Classifier Configuration > Classifier Global Setting

Table 76 Common IP Protocol Types and Protocol Numbers

PROTOCOL TYPE PROTOCOL NUMBER

ICMP 1

TCP 6

UDP 17

EGP 8

L2TP 115

Table 77 Common TCP and UDP Port Numbers

PROTOCOL NAME TCP/UDP PORT NUMBER

FTP 21

Telnet 23

SMTP 25

DNS 53

HTTP 80

POP3 110

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The following table describes the labels in this screen.

21.5 Classifier Example

The following screen shows an example where you configure a classifier that identifies all traffic from

MAC address 00:50:ba:ad:4f:81 on port 2.

After you have configured a classifier, you can configure a policy (in the Policy screen) to define

action(s) on the classified traffic flow.

Table 78 Advanced Application > Classifier > Classifier Configuration > Classifier Global Setting

LABEL DESCRIPTION

Match

Order

Select manual to have classifier rules applied according to the weight of each rule you configured in

Advanced Application > Classifier > Classifier Configuration.

Alternatively, select auto to have classifier rules applied according to the layer of the item configured

in the rule. Layer-4 items have the highest priority, and layer-2 items has the lowest priority. For

example, you configure a layer-2 item (VLAN ID) in classifier A and configure a layer-3 item (source IP

address) in classifier B. When an incoming packet matches both classifier rules, classifier B has priority

over classifier A.

Logging

Active Select this to allow the Switch to create a log when packets match a classifier rule during a defined

time interval.

Interval Select the length of the time period (in seconds) to count matched packets for a classifier rule. Enter

an integer from 0-65535. 0 means that no logging is done.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these changes if it

is turned off or loses power, so use the Save link on the top navigation panel to save your changes to

the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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Figure 147 Classifier: Example

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CHAPTER 22

Policy Rule

22.1 Policy Rules Overview

This chapter shows you how to configure policy rules.

A classifier distinguishes traffic into flows based on the configured criteria (refer to Chapter 21 on page

185 for more information). A policy rule ensures that a traffic flow gets the requested treatment in the

network.

22.1.1 What You Can Do

Use the Policy Rule screen (Section 22.2 on page 194) to enable the policy and display the active

classifier(s) you configure in the Classifier screen.

22.2 Configuring Policy Rules

You must first configure a classifier in the Classifier screen. Refer to Section 21.3 on page 186 for more

information.

Click Advanced Applications > Policy Rule in the navigation panel to display the screen as shown.

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Figure 148 Advanced Application > Policy Rule

The following table describes the labels in this screen.

Table 79 Advanced Application > Policy Rule

LABEL DESCRIPTION

Active Select this option to enable the policy.

Name Enter a descriptive name for identification purposes.

Classifier(s) This field displays the active classifier(s) you configure in the Classifier screen.

Select the classifier(s) to which this policy rule applies. To select more than one classifier, press

[SHIFT] and select the choices at the same time.

Parameters

Set the fields below for this policy. You only have to set the field(s) that is related to the action(s) you configure in

the Action field.

General

VLAN ID Specify a VLAN ID.

Egress Port Type the number of an outgoing port.

Priority Specify a priority level.

Rate Limit You can configure the desired bandwidth available to a traffic flow. Traffic that exceeds the

maximum bandwidth allocated (in cases where the network is congested) is called out-of-profile

traffic.

Bandwidth Specify the bandwidth in kilobit per second (kbps). Enter a number between 1 and 1000000.

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Action

Specify the action(s) the Switch takes on the associated classified traffic flow.

Note: You can specify only one action (pair) in a policy rule. To have the Switch take multiple actions

on the same traffic flow, you need to define multiple classifiers with the same criteria and apply

different policy rules.

Say you have several classifiers that identify the same traffic flow and you specify a different policy rule for each. If

their policy actions conflict (Discard the packet, Send the packet to the egress port and Rate Limit), the Switch only

applies the policy rules with the Discard the packet and Send the packet to the egress port actions depending on

the classifier names. The longer the classifier name, the higher the classifier priority. If two classifier names are the

same length, the bigger the character, the higher the classifier priority. The lowercase letters (such as a and b)

have higher priority than the capitals (such as A and B) in the classifier name. For example, the classifier with the

name of class 2, class a or class B takes priority over the classifier with the name of class 1 or class A.

Let’s say you set two classifiers (Class 1 and Class 2) and both identify all traffic from MAC address 11:22:33:44:55:66

on port 3.

If Policy 1 applies to Class 1 and the action is to drop the packets, Policy 2 applies to Class 2 and the action is to

forward the packets to the egress port, the Switch will forward the packets.

If Policy 1 applies to Class 1 and the action is to drop the packets, Policy 2 applies to Class 2 and the action is to

enable bandwidth limitation, the Switch will discard the packets immediately.

If Policy 1 applies to Class 1 and the action is to forward the packets to the egress port, Policy 2 applies to Class 2

and the action is to enable bandwidth limitation, the Switch will forward the packets.

Forwarding Select No change to forward the packets.

Select Discard the packet to drop the packets.

Priority Select No change to keep the priority setting of the frames.

Select Set the packet’s 802.1p priority to replace the packet’s 802.1p priority field with the value

you set in the Priority field.

Outgoing Select Send the packet to the mirror port to send the packet to the mirror port.

Select Send the packet to the egress port to send the packet to the egress port.

Select Set the packet's VLAN ID to set the packet’s VLAN ID.

Rate Limit Select Enable to activate bandwidth limitation on the traffic flow(s) then set the actions to be

taken on out-of-profile packets.

Add Click Add to inset the entry to the summary table below and save your changes to the Switch’s

run-time memory. The Switch loses these changes if it is turned off or loses power, so use the Save

link on the top navigation panel to save your changes to the non-volatile memory when you are

done configuring.

Cancel Click Cancel to reset the fields back to your previous configuration.

Clear Click Clear to set the above fields back to the factory defaults.

Index This field displays the policy index number. Click an index number to edit the policy.

Active This field displays Yes when policy is activated and No when is it deactivated.

Name This field displays the name you have assigned to this policy.

Classifier(s) This field displays the name(s) of the classifier to which this policy applies.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Click Delete to remove the selected entry from the summary table.

Cancel Click Cancel to clear the check boxes.

Table 79 Advanced Application > Policy Rule (continued)

LABEL DESCRIPTION

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22.3 Policy Example

The figure below shows an example Policy screen where you configure a policy to limit bandwidth on a

traffic flow classified using the Example classifier (refer to Section 21.5 on page 192).

Figure 149 Policy Example

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CHAPTER 23

Queuing Method

23.1 Queuing Method Overview

This chapter introduces the queuing methods supported.

Queuing is used to help solve performance degradation when there is network congestion. Use the

Queuing Method screen to configure queuing algorithms for outgoing traffic. See also Priority Queue

Assignment in Switch Setup and 802.1p Priority in Port Setup for related information.

23.1.1 What You Can Do

Use the Queuing Method screen (Section 23.2 on page 199) set priorities for the queues of the Switch.

This distributes bandwidth across the different traffic queues.

23.1.2 What You Need to Know

Queuing algorithms allow switches to maintain separate queues for packets from each individual

source or flow and prevent a source from monopolizing the bandwidth.

Strictly Priority Queuing

Strictly Priority Queuing (SPQ) services queues based on priority only. As traffic comes into the Switch,

traffic on the highest priority queue, Q7 is transmitted first. When that queue empties, traffic on the next

highest-priority queue, Q6 is transmitted until Q6 empties, and then traffic is transmitted on Q5 and so on.

If higher priority queues never empty, then traffic on lower priority queues never gets sent. SPQ does not

automatically adapt to changing network requirements.

Weighted Fair Queuing

Weighted Fair Queuing is used to guarantee each queue's minimum bandwidth based on its bandwidth

weight (portion) (the number you configure in the Weight field) when there is traffic congestion. WFQ is

activated only when a port has more traffic than it can handle. Queues with larger weights get more

guaranteed bandwidth than queues with smaller weights. This queuing mechanism is highly efficient in

that it divides any available bandwidth across the different traffic queues. By default, the weight for Q0

is 1, for Q1 is 2, for Q2 is 3, and so on.

Weighted Round Robin Scheduling (WRR)

Round Robin Scheduling services queues on a rotating basis and is activated only when a port has more

traffic than it can handle. A queue is a given an amount of bandwidth irrespective of the incoming

traffic on that port. This queue then moves to the back of the list. The next queue is given an equal

amount of bandwidth, and then moves to the end of the list; and so on, depending on the number of

queues being used. This works in a looping fashion until a queue is empty.

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Weighted Round Robin Scheduling (WRR) uses the same algorithm as round robin scheduling, but

services queues based on their priority and queue weight (the number you configure in the queue

Weight field) rather than a fixed amount of bandwidth. WRR is activated only when a port has more

traffic than it can handle. Queues with larger weights get more service than queues with smaller

weights. This queuing mechanism is highly efficient in that it divides any available bandwidth across the

different traffic queues and returns to queues that have not yet emptied.

23.2 Configuring Queuing

Use this screen to set priorities for the queues of the Switch. This distributes bandwidth across the different

traffic queues.

Click Advanced Application > Queuing Method in the navigation panel.

Figure 150 Advanced Application > Queuing Method

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The following table describes the labels in this screen.

Table 80 Advanced Application > Queuing Method

LABEL DESCRIPTION

Port This label shows the port you are configuring. * means all ports.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set the

common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Method Select SPQ (Strictly Priority Queuing), WFQ (Weighted Fair Queuing) or WRR (Weighted Round Robin).

Strictly Priority Queuing services queues based on priority only. When the highest priority queue

empties, traffic on the next highest-priority queue begins. Q7 has the highest priority and Q0 the

lowest.

Weighted Fair Queuing is used to guarantee each queue's minimum bandwidth based on their

bandwidth portion (weight) (the number you configure in the Weight field). Queues with larger

weights get more guaranteed bandwidth than queues with smaller weights.

Weighted Round Robin Scheduling services queues on a rotating basis based on their queue weight

(the number you configure in the queue Weight field). Queues with larger weights get more service

than queues with smaller weights.

Weight When you select WFQ or WRR enter the queue weight here. Bandwidth is divided across the different

traffic queues according to their weights.

Hybrid-SPQ

Lowest-

Queue

This field is applicable only when you select WFQ or WRR.

Select a queue (Q0 to Q7) to have the Switch use SPQ to service the subsequent queue(s) after and

including the specified queue for the port. For example, if you select Q5, the Switch services traffic on

Q5, Q6 and Q7 using SPQ.

Select None to always use WFQ or WRR for the port.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these changes if

it is turned off or loses power, so use the Save link on the top navigation panel to save your changes to

the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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CHAPTER 24

Multicast

24.1 Multicast Overview

This chapter shows you how to configure various multicast features.

Traditionally, IP packets are transmitted in one of either two ways - Unicast (1 sender to 1 recipient) or

Broadcast (1 sender to everybody on the network). Multicast delivers IP packets to just a group of hosts

on the network.

IGMP (Internet Group Management Protocol) is a network-layer protocol used to establish membership

in a multicast group - it is not used to carry user data. Refer to RFC 1112, RFC 2236 and RFC 3376 for

information on IGMP versions 1, 2 and 3 respectively.

24.1.1 What You Can Do

• Use the Multicast Setup screen (Section 24.2 on page 205) to display the links to the configuration

screens where you can configure IPv4 or IPv6 multicast settings.

• Use the IPv4 Multicast Status screen (Section 24.3 on page 205) to view multicast group information.

• Use the IGMP Snooping screen (Section 24.3.1 on page 206) to enable IGMP snooping to forward

group multicast traffic only to ports that are members of that group.

• Use the IGMP Snooping VLAN screen (Section 24.3.2 on page 209) to perform IGMP snooping on up to

16 VLANs.

• Use the IGMP Filtering Profile (Section 24.3.3 on page 210) to specify a range of multicast groups that

clients connected to the Switch are able to join.

• Use the IPv6 Multicast Status screen (Section 24.4 on page 211) to view multicast group information,

• Use the MLD Snooping-proxy screen (Section 24.4.1 on page 212) to enable the upstream port to

report group changes to a connected multicast router and forward MLD messages to other upstream

ports.

• Use the MVR screens (Section 24.5 on page 218) to create multicast VLANs and select the receiver

port(s) and a source port for each multicast VLAN.

24.1.2 What You Need to Know

Read on for concepts on Multicasting that can help you configure the screens in this chapter.

IP Multicast Addresses

In IPv4, a multicast address allows a device to send packets to a specific group of hosts (multicast

group) in a different subnetwork. A multicast IP address represents a traffic receiving group, not

individual receiving devices. IP addresses in the Class D range (224.0.0.0 to 239.255.255.255) are used for

IP multicasting. Certain IP multicast numbers are reserved by IANA for special purposes (see the IANA

website for more information).

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IGMP Snooping

A Switch can passively snoop on IGMP packets transferred between IP multicast routers/switches and IP

multicast hosts to learn the IP multicast group membership. It checks IGMP packets passing through it,

picks out the group registration information, and configures multicasting accordingly. IGMP snooping

allows the Switch to learn multicast groups without you having to manually configure them.

The Switch forwards multicast traffic destined for multicast groups (that it has learned from IGMP

snooping or that you have manually configured) to ports that are members of that group. IGMP

snooping generates no additional network traffic, allowing you to significantly reduce multicast traffic

passing through your Switch.

IGMP Snooping and VLANs

The Switch can perform IGMP snooping on up to 16 VLANs. You can configure the Switch to

automatically learn multicast group membership of any VLANs. The Switch then performs IGMP

snooping on the first 16 VLANs that send IGMP packets. This is referred to as auto mode. Alternatively,

you can specify the VLANs that IGMP snooping should be performed on. This is referred to as fixed

mode. In fixed mode the Switch does not learn multicast group membership of any VLANs other than

those explicitly added as an IGMP snooping VLAN.

MLD Snooping-proxy

MLD snooping-proxy is a Zyxel-proprietary feature. IPv6 MLD proxy allows only one upstream interface on

a switch, while MLD snooping-proxy supports more than one upstream port on a switch. The upstream

port in MLD snooping-proxy can report group changes to a connected multicast router and forward

MLD messages to other upstream ports. This helps especially when you want to have a network that uses

STP to provide backup links between switches and also performs MLD snooping and proxy functions.

MLD snooping-proxy, like MLD proxy, can minimize MLD control messages and allow better network

performance.

In MLD snooping-proxy, if one upstream port is learned via snooping, all other upstream ports on the

same device will be added to the same group. If one upstream port requests to leave a group, all other

upstream ports on the same device will also be removed from the group.

In the following MLD snooping-proxy example, all connected upstream ports (1 ~7) are treated as one

interface. The connection between ports 8 and 9 is blocked by STP to break the loop. If there is one

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query from a router (X) or MLD Done or Report message from any upstream port, it will be broadcast to

all connected upstream ports.

MLD Messages

A multicast router or switch periodically sends general queries to MLD hosts to update the multicast

forwarding table. When an MLD host wants to join a multicast group, it sends an MLD Report message

for that address.

An MLD Done message is similar to an IGMP Leave message. When an MLD host wants to leave a

multicast group, it can send a Done message to the router or switch. If the leave mode is not set to

Immediate, the router or switch sends a group-specific query to the port on which the Done message is

received to determine if other devices connected to this port should remain in the group.

MVR Overview

Multicast VLAN Registration (MVR) is designed for applications (such as Media-on-Demand (MoD)) that

use multicast traffic across an Ethernet ring-based service provider network.

MVR allows one single multicast VLAN to be shared among different subscriber VLANs on the network.

While isolated in different subscriber VLANs, connected devices can subscribe to and unsubscribe from

the multicast stream in the multicast VLAN. This improves bandwidth utilization with reduced multicast

traffic in the subscriber VLANs and simplifies multicast group management.

MVR only responds to IGMP join and leave control messages from multicast groups that are configured

under MVR. Join and leave reports from other multicast groups are managed by IGMP snooping.

The following figure shows a network example. The subscriber VLAN (1, 2 and 3) information is hidden

from the streaming media server, S. In addition, the multicast VLAN information is only visible to the

Switch and S.

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Figure 151 MVR Network Example

Types of MVR Ports

In MVR, a source port is a port on the Switch that can send and receive multicast traffic in a multicast

VLAN while a receiver port can only receive multicast traffic. Once configured, the Switch maintains a

forwarding table that matches the multicast stream to the associated multicast group.

MVR Modes

You can set your Switch to operate in either dynamic or compatible mode.

In dynamic mode, the Switch sends IGMP leave and join reports to the other multicast devices (such as

multicast routers or servers) in the multicast VLAN. This allows the multicast devices to update the

multicast forwarding table to forward or not forward multicast traffic to the receiver ports.

In compatible mode, the Switch does not send any IGMP reports. In this case, you must manually

configure the forwarding settings on the multicast devices in the multicast VLAN.

How MVR Works

The following figure shows a multicast television example where a subscriber device (such as a

computer) in VLAN 1 receives multicast traffic from the streaming media server, S, via the Switch.

Multiple subscriber devices can connect through a port configured as the receiver on the Switch.

When the subscriber selects a television channel, computer A sends an IGMP report to the Switch to join

the appropriate multicast group. If the IGMP report matches one of the configured MVR multicast group

addresses on the Switch, an entry is created in the forwarding table on the Switch. This maps the

subscriber VLAN to the list of forwarding destinations for the specified multicast traffic.

When the subscriber changes the channel or turns off the computer, an IGMP leave message is sent to

the Switch to leave the multicast group. The Switch sends a query to VLAN 1 on the receiver port (in this

case, an uplink port on the Switch). If there is another subscriber device connected to this port in the

same subscriber VLAN, the receiving port will still be on the list of forwarding destination for the multicast

traffic. Otherwise, the Switch removes the receiver port from the forwarding table.

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Figure 152 MVR Multicast Television Example

24.2 Multicast Setup

Use this screen to configure IGMP for IPv4 or MLD for IPv6 and set up multicast VLANs. Click Advanced

Application > Multicast in the navigation panel.

Figure 153 Advanced Application > Multicast Setup

The following table describes the labels in this screen.

24.3 IPv4 Multicast Status

Click Advanced Application > Multicast > IPv4 Multicast to display the screen as shown. This screen

shows the IPv4 multicast group information. See Section 24.1 on page 201 for more information on

multicasting.

Figure 154 Advanced Application > Multicast > IPv4 Multicast

Table 81 Advanced Application > Multicast Setup

LABEL DESCRIPTION

IPv4 Multicast Click the link to open screens where you can configure IGMP snooping and IGMP filtering for

IPv4.

IPv6 Multicast Click the link to open screens where you can configure MLD snooping-proxy and MLD filtering

for IPv6.

MVR Click the link to open screens where you can create multicast VLANs.

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The following table describes the labels in this screen.

24.3.1 IGMP Snooping

Click the IGMP Snooping link in the Advanced Application > Multicast > IPv4 Multicast screen to display

the screen as shown. See Section 24.1 on page 201 for more information on multicasting.

Figure 155 Advanced Application > Multicast > IPv4 Multicast > IGMP Snooping

The following table describes the labels in this screen.

Table 82 Advanced Application > Multicast > IPv4 Multicast

LABEL DESCRIPTION

Index This is the index number of the entry.

VID This field displays the multicast VLAN ID.

Port This field displays the port number that belongs to the multicast group.

Multicast Group This field displays IP multicast group addresses.

Table 83 Advanced Application > Multicast > IPv4 Multicast > IGMP Snooping

LABEL DESCRIPTION

IGMP Snooping Use these settings to configure IGMP snooping.

Active Select Active to enable IGMP Snooping to forward group multicast traffic only to ports that

are members of that group.

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Querier Select this option to allow the Switch to send IGMP General Query messages to the VLANs with

the multicast hosts attached.

Report Proxy Select this option to allow the Switch to act as the IGMP report proxy and leave proxy. It will

report group changes to a connected multicast router.

The Switch not only checks IGMP packets between multicast routers/switches and multicast

hosts to learn the multicast group membership, but also replaces the source MAC address in

an IGMP v1/v2 report with its own MAC address before forwarding to the multicast router/

switch. When the Switch receives more than one IGMP v1/v2 join report that requests to join

the same multicast group, it only sends a new join report with its MAC address. This helps

reduce the number of multicast join reports passed to the multicast router/switch.

The Switch sends a leave message with its MAC address to the multicast router/switch only

when it receives the leave message from the last host in a multicast group.

Host Timeout Specify the time (from 1 to 16 711 450) in seconds that elapses before the Switch removes an

IGMP group membership entry if it does not receive report messages from the port.

802.1p Priority Select a priority level (0-7) to which the Switch changes the priority in outgoing IGMP control

packets. Otherwise, select No-Change to not replace the priority.

IGMP Filtering Select Active to enable IGMP filtering to control which IGMP groups a subscriber on a port

can join.

If you enable IGMP filtering, you must create and assign IGMP filtering profiles for the ports that

you want to allow to join multicast groups.

Unknown Multicast

Frame

Specify the action to perform when the Switch receives an unknown multicast frame.

•Select Drop to discard the frame(s).

•Select Flooding to send the frame(s) to all ports.

•Select Drop on VLAN and enter the VLAN ID number(s) to discard the frame(s) on the

specified VLAN(s). Use a dash to specify consecutive VLANs and a comma (no spaces) to

specify non-consecutive VLANs. For example, 51-53 includes 51, 52 and 53, but 51,53 does

not include 52.

Unknown Multicast

Frame to Querier

Port

Specify the action to perform when Unknown Multicast Frame is set to Drop.

•Select Drop to discard the frame(s).

•Select Forwarding to send the frame(s) to all querier ports.

•Select Forwarding on VLAN and enter the VLAN ID number(s) to send the frame(s) to the

ports which are used as an IGMP query port on the specified VLAN(s). Use a dash to

specify consecutive VLANs and a comma (no spaces) to specify non-consecutive VLANs.

For example, 51-53 includes 51, 52 and 53, but 51,53 does not include 52.

Reserved Multicast

Group

The IP address range of 224.0.0.0 to 224.0.0.255 are reserved for multicasting on the local

network only. For example, 224.0.0.1 is for all hosts on a local network segment and 224.0.0.9 is

used to send RIP routing information to all RIP v2 routers on the same network segment. A

multicast router will not forward a packet with the destination IP address within this range to

other networks. See the IANA web site for more information.

The layer-2 multicast MAC addresses used by Cisco layer-2 protocols, 01:00:0C:CC:CC:CC

and 01:00:0C:CC:CC:CD, are also included in this group.

Specify the action to perform when the Switch receives a frame with a reserved multicast

address.

•Select Drop to discard the frame(s).

•Select Flooding to send the frame(s) to all ports.

Port This field displays the port number. * means all ports.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Changes in this row are copied to all the ports as soon as you make them.

Table 83 Advanced Application > Multicast > IPv4 Multicast > IGMP Snooping (continued)

LABEL DESCRIPTION

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Immed. Leave Select this option to set the Switch to remove this port from the multicast tree when an IGMP

version 2 leave message is received on this port.

Select this option if there is only one host connected to this port.

Normal Leave Enter an IGMP normal leave timeout value (from 200 to 6,348,800) in miliseconds. Select this

option to have the Switch use this timeout to update the forwarding table for the port.

In normal leave mode, when the Switch receives an IGMP leave message from a host on a

port, it forwards the message to the multicast router. The multicast router then sends out an

IGMP Group-Specific Query (GSQ) message to determine whether other hosts connected to

the port should remain in the specific multicast group. The Switch forwards the query message

to all hosts connected to the port and waits for IGMP reports from hosts to update the

forwarding table.

This defines how many seconds the Switch waits for an IGMP report before removing an IGMP

snooping membership entry when an IGMP leave message is received on this port from a

host.

Fast Leave Enter an IGMP fast leave timeout value (from 200 to 6,348,800) in miliseconds. Select this

option to have the Switch use this timeout to update the forwarding table for the port.

In fast leave mode, right after receiving an IGMP leave message from a host on a port, the

Switch itself sends out an IGMP Group-Specific Query (GSQ) message to determine whether

other hosts connected to the port should remain in the specific multicast group. This helps

speed up the leave process.

This defines how many seconds the Switch waits for an IGMP report before removing an IGMP

snooping membership entry when an IGMP leave message is received on this port from a

host.

Group Limited Select this option to limit the number of multicast groups this port is allowed to join.

Max Group Num. Enter the number of multicast groups this port is allowed to join. Once a port is registered in the

specified number of multicast groups, any new IGMP join report frame(s) is dropped on this

port.

Throttling IGMP throttling controls how the Switch deals with the IGMP reports when the maximum

number of the IGMP groups a port can join is reached.

Select Deny to drop any new IGMP join report received on this port until an existing multicast

forwarding table entry is aged out.

Select Replace to replace an existing entry in the multicast forwarding table with the new

IGMP report(s) received on this port.

IGMP Filtering

Profile

Select the name of the IGMP filtering profile to use for this port. Otherwise, select Default to

prohibit the port from joining any multicast group.

You can create IGMP filtering profiles in the Multicast > IPv4 Multicast > IGMP Snooping > IGMP

Filtering Profile screen.

IGMP Querier

Mode

The Switch treats an IGMP query port as being connected to an IGMP multicast router (or

server). The Switch forwards IGMP join or leave packets to an IGMP query port.

Select Auto to have the Switch use the port as an IGMP query port if the port receives IGMP

query packets.

Select Fixed to have the Switch always use the port as an IGMP query port. Select this when

you connect an IGMP multicast server to the port.

Select Edge to stop the Switch from using the port as an IGMP query port. The Switch will not

keep any record of an IGMP router being connected to this port. The Switch does not forward

IGMP join or leave packets to this port.

Table 83 Advanced Application > Multicast > IPv4 Multicast > IGMP Snooping (continued)

LABEL DESCRIPTION

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24.3.2 IGMP Snooping VLAN

Click Advanced Application > Multicast > IPv4 Multicast in the navigation panel. Click the IGMP

Snooping link and then the IGMP Snooping VLAN link to display the screen as shown. See IGMP Snooping

and VLANs on page 202 for more information on IGMP Snooping VLAN.

Figure 156 Advanced Application > Multicast > IPv4 Multicast > IGMP Snooping > IGMP Snooping VLAN

The following table describes the labels in this screen.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 83 Advanced Application > Multicast > IPv4 Multicast > IGMP Snooping (continued)

LABEL DESCRIPTION

Table 84 Advanced Application > Multicast > IPv4 Multicast > IGMP Snooping > IGMP Snooping VLAN

LABEL DESCRIPTION

Mode Specifies how the VLANs on which the Switch snoops IGMP packets are selected.

•Select auto to have the Switch learn multicast group membership information of any

VLANs automatically.

•Select fixed to have the Switch only learn multicast group membership information of the

VLAN(s) that you specify below.

Note: In either auto or fixed mode, the Switch can learn up to 16 VLANs.

Note: The Switch drops any IGMP control messages which do not belong to these

16 VLANs.

You must also enable IGMP snooping in the Multicast > IPv4 Multicast > IGMP Snooping screen

first.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

VLAN Use this section of the screen to add VLANs upon which the Switch is to perform IGMP

snooping.

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24.3.3 IGMP Filtering Profile

An IGMP filtering profile specifies a range of multicast groups that clients connected to the Switch are

able to join. A profile contains a range of multicast IP addresses which you want clients to be able to

join. Profiles are assigned to ports (in the IGMP Snooping screen). Clients connected to those ports are

then able to join the multicast groups specified in the profile. Each port can be assigned a single profile.

A profile can be assigned to multiple ports.

Click Advanced Application > Multicast > IPv4 Multicast in the navigation panel. Click the IGMP

Snooping link and then the IGMP Filtering Profile link to display the screen as shown.

Figure 157 Advanced Application > Multicast > IPv4 Multicast > IGMP Snooping > IGMP Filtering Profile

Name Enter the descriptive name of the VLAN for identification purposes.

VID Enter the ID of a static VLAN; the valid range is between 1 and 4094.

Add Click this to create a new entry or to update an existing one.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your

changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to your previous configuration.

Clear Click Clear to reset the fields to the factory defaults.

Index This is the index number of the IGMP snooping VLAN entry in the table. Click on an index

number to view more details or change the settings.

Name This field displays the descriptive name for this VLAN group.

VID This field displays the ID number of the VLAN group.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Check the entry(ies) that you want to remove, then click the Delete button.

Cancel Click Cancel to clear the check boxes.

Table 84 Advanced Application > Multicast > IPv4 Multicast > IGMP Snooping > IGMP Snooping VLAN

LABEL DESCRIPTION

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The following table describes the labels in this screen.

24.4 IPv6 Multicast Status

Click Advanced Application > Multicast > IPv6 Multicast to display the screen as shown. This screen

shows the IPv6 multicast group information. See Section 24.1 on page 201 for more information on

multicasting.

Figure 158 Advanced Application > Multicast > IPv6 Multicast

The following table describes the fields in the above screen.

Table 85 Advanced Application > Multicast > IPv4 Multicast > IGMP Snooping > IGMP Filtering Profile

LABEL DESCRIPTION

Profile Name Enter a descriptive name for the profile for identification purposes.

To configure additional rule(s) for a profile that you have already added, enter the profile

name and specify a different IP multicast address range.

Start Address Type the starting multicast IP address for a range of multicast IP addresses that you want to

belong to the IGMP filter profile.

End Address Type the ending multicast IP address for a range of IP addresses that you want to belong to

the IGMP filter profile.

If you want to add a single multicast IP address, enter it in both the Start Address and End

Address fields.

Add Click this to create a new entry.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your

changes to the non-volatile memory when you are done configuring.

Clear Click Clear to reset the fields to the factory defaults.

Profile Name This field displays the descriptive name of the profile.

Start Address This field displays the start of the multicast address range.

End Address This field displays the end of the multicast address range.

Delete Profile Select a profile’s check box to select a specific profile. Otherwise, select the check box in the

table heading row to select all profiles.

Delete Rule Select the check box(es) of the rule(s) that you want to remove from a profile.

Delete To delete the profile(s) and all the accompanying rules, select the profile(s) that you want to

remove in the Delete Profile column, then click the Delete button.

To delete a rule(s) from a profile, select the rule(s) that you want to remove in the Delete Rule

column, then click the Delete button.

Cancel Click Cancel to clear the Delete Profile/Delete Rule check boxes.

Table 86 Advanced Application > Multicast > IPv6 Multicast

LABEL DESCRIPTION

Index This is the index number of the entry.

VID This field displays the multicast VLAN ID.

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24.4.1 MLD Snooping-proxy

Click the MLD Snooping-proxy link in the Advanced Application > Multicast > IPv6 Multicast screen to

display the screen as shown. See Section 24.1 on page 201 for more information on multicasting.

Figure 159 Advanced Application > Multicast > IPv6Multicast > MLD Snooping-proxy

The following table describes the fields in the above screen.

24.4.2 MLD Snooping-proxy VLAN

Click the VLAN link in the Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy

screen to display the screen as shown. See Section 24.1 on page 201 for more information on

multicasting.

Port This field displays the port number that belongs to the multicast group.

Multicast Group This field displays IP multicast group addresses.

Group Timeout This field displays the time (in seconds) that elapses before the Switch removes a MLD group

membership entry if it does not receive report messages from the port.

Table 86 Advanced Application > Multicast > IPv6 Multicast

LABEL DESCRIPTION

Table 87 Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy

LABEL DESCRIPTION

MLD Snooping-proxy Use these settings to configure MLD snooping-proxy.

Active Select Active to enable MLD snooping-proxy on the Switch to minimize MLD control

messages and allow better network performance.

802.1p Priority Select a priority level (0-7) to which the Switch changes the priority in outgoing MLD

messages.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel

to save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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Figure 160 Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy > VLAN

The following table describes the fields in the above screen.

Table 88 Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy > VLAN

LABEL DESCRIPTION

VID Enter the ID number of the VLAN on which you want to enable MLD snooping-proxy and

configure related settings.

Upstream

Query Interval Enter the amount of time (in miliseconds) between general query messages sent by the

router connected to the upstream port. This value should be exactly the same as what’s

configured in the connected multicast router.

This value is used to calculate the amount of time an MLD snooping membership entry

(learned only on the upstream port) can remain in the forwarding table.

When an MLD Report message is received, the Switch sets the timeout period of the entry

to be T = (QI*RV) + MRD, where T = Timeout, QI = Query Interval, RV = Robustness Variable,

and MRD = Maximum Response Delay.

Maximum Response

Delay

Enter the amount of time (in miliseconds) the router connected to the upstream port waits

for a response to an MLD general query message. This value should be exactly the same

as what’s configured in the connected multicast router.

This value is used to calculate the amount of time an MLD snooping membership entry

(learned only on the upstream port) can remain in the forwarding table.

When an MLD Report message is received, the Switch sets the timeout period of the entry

to be T = (QI*RV) + MRD, where T = Timeout, QI = Query Interval, RV = Robustness Variable,

and MRD = Maximum Response Delay.

When an MLD Done message is received, the Switch sets the entry’s lifetime to be the

product of Last Member Query Interval and Robustness Variable.

Robustness Variable Enter the number of queries. A multicast address entry (learned only on an upstream port

by snooping) is removed from the forwarding table when there is no response to the

configured number of queries sent by the router connected to the upstream port. This

value should be exactly the same as what’s configured in the connected multicast

router.

This value is used to calculate the amount of time an MLD snooping membership entry

(learned only on the upstream port) can remain in the forwarding table.

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24.4.3 MLD Snooping-proxy VLAN Port Role Setting

Click the Port Role Setting link in the Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-

proxy > VLAN screen to display the screen as shown. See Section 24.1 on page 201 for more information

on multicasting.

Last Member Query

Interval

Enter the amount of time (in miliseconds) between the MLD group-specific queries sent by

an upstream port when an MLD Done message is received. This value should be exactly

the same as what’s configured in the connected multicast router.

This value is used to calculate the amount of time an MLD snooping membership entry

(learned only on the upstream port) can remain in the forwarding table after a Done

message is received.

When an MLD Done message is received, the Switch sets the entry’s lifetime to be the

product of Last Member Query Interval and Robustness Variable.

Downstream

Query Interval Enter the amount of time (in miliseconds) between general query messages sent by the

downstream port.

Maximum Response

Delay

Enter the maximum time (in miliseconds) that the Switch waits for a response to a general

query message sent by the downstream port.

Add Click this to create a new entry or to update an existing one.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes

if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to your previous configuration.

Clear Click Clear to reset the fields to the factory defaults.

Index This is the index number of the MLD snooping-proxy VLAN entry in the table. Click on an

index number to view more details or change the settings.

VID This field displays the ID number of the VLAN group.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in

the table heading row to select all entries.

Delete Click Delete to remove the selected entry(ies) permanently.

Cancel Click Cancel to clear the check boxes.

Table 88 Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy > VLAN

LABEL DESCRIPTION

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Figure 161 Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy > Port Role Setting

The following table describes the fields in the above screen.

Table 89 Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy > Port Role Setting

LABEL DESCRIPTION

MLD Snooping-proxy

VLAN ID

Select the VLAN ID for which you want to configure a port’s MLD snooping-proxy settings.

Port This field displays the port number.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first

to set the common settings and then make adjustments on a port-by-port basis.

Changes in this row are copied to all the ports as soon as you make them.

Port Role A port on the Switch can be either a Downstream port or Upstream port in MLD. A

downstream port connects to MLD hosts and acts as a multicast router to send MLD

queries and listen to the MLD host’s Report and Done messages. An upstream port

connects to a multicast router and works as a host to send Report or Done messages

when receiving queries from a multicast router.

Otherwise, select None if the port is not joining a multicast group or does not belong to

this VLAN.

Leave Mode Select the leave mode for the specified downstream port(s) in this VLAN.

This specifies whether the Switch removes an MLD snooping membership entry (learned

on a downstream port) immediately (Immediate) or wait for an MLD report before the

leave timeout (Normal) or fast leave timeout (Fast) when an MLD leave message is

received on this port from a host.

Leave Timeout Enter the MLD snooping normal leave timeout (in milliseconds) the Switch uses to update

the forwarding table for the specified downstream port(s).

This defines how many seconds the Switch waits for an MLD report before removing an

MLD snooping membership entry (learned on a downstream port) when an MLD Done

message is received on this port from a host.

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24.4.4 MLD Snooping-proxy Filtering

Use this screen to configure the Switch’s MLD filtering settings. Click the Filtering link in the Advanced

Application > Multicast > IPv6 Multicast > MLD Snooping-proxy screen to display the screen as shown.

Figure 162 Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy > Filtering

The following table describes the fields in the above screen.

Fast Leave Timeout Enter the fast leave timeout (in milliseconds) for the specified downstream port(s).

This defines how many seconds the Switch waits for an MLD report before removing an

MLD snooping membership entry (learned on a downstream port) when an MLD Done

message is received on this port from a host.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses

these changes if it is turned off or loses power, so use the Save link on the top navigation

panel to save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to your previous configuration.

Table 89 Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy > Port Role Setting

LABEL DESCRIPTION

Table 90 Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy > Filtering

LABEL DESCRIPTION

Active Select this option to enable MLD filtering on the Switch.

Port This field displays the port number.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to

set the common settings and then make adjustments on a port-by-port basis.

Changes in this row are copied to all the ports as soon as you make them.

Group Limit Select this option to limit the number of multicast groups this port is allowed to join.

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24.4.5 MLD Snooping-proxy Filtering Profile

Use this screen to create an MLD filtering profile and set the range of the multicast address(es). Click the

Filtering Profile link in the Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy >

Filtering screen to display the screen as shown.

Figure 163 Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy > Filtering >

Filtering Profile

The following table describes the fields in the above screen.

Max Group Num. Enter the number of multicast groups this port is allowed to join. Once a port is registered in

the specified number of multicast groups, any new MLD Report message is dropped on this

port.

Filtering Profile Select the name of the MLD filtering profile to use for this port. Otherwise, select Default to

prohibit the port from joining any multicast group.

You can create MLD filtering profiles in the Multicast > IPv6 Multicast > MLD Snooping-proxy

> Filtering > Filtering Profile screen.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to your previous configuration.

Table 90 Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy > Filtering

LABEL DESCRIPTION

Table 91 Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy > Filtering Profile

LABEL DESCRIPTION

Profile Name Enter a descriptive name for the profile for identification purposes.

To configure additional rule(s) for a profile that you have already added, enter the profile

name and specify a different IP multicast address range.

Start Address Type the starting multicast IPv6 address for a range of multicast IPv6 addresses that you want

to belong to the MLD filtering profile.

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24.5 General MVR Configuration

Use the MVR screen to create multicast VLANs and select the receiver port(s) and a source port for

each multicast VLAN. Click Advanced Application > Multicast > MVR to display the screen as shown

next.

Note: You can create up to five multicast VLANs and up to 256 multicast rules on the Switch.

Note: Your Switch automatically creates a static VLAN (with the same VID) when you create

a multicast VLAN in this screen.

End Address Type the ending multicast IPv6 address for a range of IPv6 addresses that you want to

belong to the MLD filtering profile.

If you want to add a single multicast IPv6 address, enter it in both the Start Address and End

Address fields.

Add Click this to create a new entry.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it

is turned off or loses power, so use the Save link on the top navigation panel to save your

changes to the non-volatile memory when you are done configuring.

Clear Click Clear to reset the fields to the factory defaults.

Profile Name This field displays the descriptive name of the profile.

Start Address This field displays the start of the multicast IPv6 address range.

End Address This field displays the end of the multicast IPv6 address range.

To delete the profile(s) and all the accompanying rules, select the profile(s) that you want to

remove, then click the Delete button. You can select the check box in the table heading

row to select all profiles.

To delete a rule(s) from a profile, select the rule(s) that you want to remove , then click the

Delete button.

Delete Click Delete button to permanently delete the entries you selected.

Cancel Click Cancel to clear the check boxes.

Table 91 Advanced Application > Multicast > IPv6 Multicast > MLD Snooping-proxy > Filtering Profile

LABEL DESCRIPTION

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Figure 164 Advanced Application > Multicast > MVR

The following table describes the related labels in this screen.

Table 92 Advanced Application > Multicast > MVR

LABEL DESCRIPTION

Active Select this check box to enable MVR to allow one single multicast VLAN to be shared among

different subscriber VLANs on the network.

Group Name Enter a descriptive name (up to 32 printable ASCII characters) for identification purposes.

Multicast VLAN ID Enter the VLAN ID (1 to 4094) of the multicast VLAN.

802.1p Priority Select a priority level (0-7) with which the Switch replaces the priority in outgoing IGMP or MLD

control packets (belonging to this multicast VLAN).

Mode Specify the MVR mode on the Switch. Choices are Dynamic and Compatible.

Select Dynamic to send IGMP reports or MLD messages to all MVR source ports in the multicast

VLAN.

Select Compatible to set the Switch not to send IGMP reports or MLD messages.

Port This field displays the port number on the Switch.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to

set the common settings and then make adjustments on a port-by-port basis.

Changes in this row are copied to all the ports as soon as you make them.

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24.5.1 MVR Group Configuration

All source ports and receiver ports belonging to a multicast group can receive multicast data sent to this

multicast group.

Use this screen to configure MVR IP multicast group address(es). Click the Group Configuration link in the

MVR screen.

Note: A port can belong to more than one multicast VLAN. However, IP multicast group

addresses in different multicast VLANs cannot overlap.

Source Port Select this option to set this port as the MVR source port that sends and receives multicast

traffic. All source ports must belong to a single multicast VLAN.

Receiver Port Select this option to set this port as a receiver port that only receives multicast traffic.

None Select this option to set the port not to participate in MVR. No MVR multicast traffic is sent or

received on this port.

Tagging Select this checkbox if you want the port to tag the VLAN ID in all outgoing frames

transmitted.

Add Click this to create a new entry or to update an existing one.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your

changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

VLAN This field displays the multicast VLAN ID. Click on an index number to change the settings.

Active This field displays whether the multicast group is enabled or not.

Name This field displays the descriptive name for this setting.

Mode This field displays the MVR mode.

Source Port This field displays the source port number(s).

Receiver Port This field displays the receiver port number(s).

802.1p This field displays the priority level.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete To delete a multicast VLAN(s), select the rule(s) that you want to remove, then click the Delete

button.

Cancel Click Cancel to clear the check boxes.

Table 92 Advanced Application > Multicast > MVR (continued)

LABEL DESCRIPTION

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Figure 165 Advanced Application > Multicast > MVR > Group Configuration

The following table describes the labels in this screen.

Table 93 Advanced Application > Multicast > MVR > Group Configuration

LABEL DESCRIPTION

Multicast VLAN ID Select a multicast VLAN ID (that you configured in the MVR screen) from the drop-down list

box.

Group Name Enter a descriptive name for identification purposes.

Start Address Enter the starting IP multicast address of the multicast group in dotted decimal notation.

Refer to IP Multicast Addresses on page 201 for more information on IP multicast addresses.

End Address Enter the ending IP multicast address of the multicast group in dotted decimal notation.

Enter the same IP address as the Start Address field if you want to configure only one IP

address for a multicast group.

Refer to IP Multicast Addresses on page 201 for more information on IP multicast addresses.

Add Click this to create a new entry.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your

changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

MVLAN This field displays the multicast VLAN ID.

Group Name This field displays the descriptive name for this setting.

Start Address This field displays the starting IP address of the multicast group.

End Address This field displays the ending IP address of the multicast group.

To delete the profile(s) and all the accompanying rules, select the profile(s) that you want to

remove, then click the Delete button. You can select the check box in the table heading row

to select all profiles.

To delete a rule(s) from a profile, select the rule(s) that you want to remove , then click the

Delete button.

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24.5.2 MVR Configuration Example

The following figure shows a network example where ports 1, 2 and 3 on the Switch belong to VLAN 1. In

addition, port 7 belongs to the multicast group with VID 200 to receive multicast traffic (the News and

Movie channels) from the remote streaming media server, S. Computers A, B and C in VLAN 1 are able

to receive the traffic.

Figure 166 MVR Configuration Example

To configure the MVR settings on the Switch, create a multicast VLAN in the MVR screen and set the

receiver and source ports.

Figure 167 MVR Configuration Example

Delete Select the entry(ies) that you want to remove, then click the Delete button to remove the

selected entry(ies) from the table.

If you delete a multicast VLAN, all multicast groups in this VLAN will also be removed.

Cancel Select Cancel to clear the checkbox(es) in the table.

Table 93 Advanced Application > Multicast > MVR > Group Configuration (continued)

LABEL DESCRIPTION

EXAMPLE

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To set the Switch to forward the multicast group traffic to the subscribers, configure multicast group

settings in the Group Configuration screen. The following figure shows an example where two IPv4

multicast groups (News and Movie) are configured for the multicast VLAN 200.

Figure 168 MVR Group Configuration Example-1

Figure 169 MVR Group Configuration Example-2

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CHAPTER 25

AAA

25.1 AAA Overview

This chapter describes how to configure authentication, authorization and accounting settings on the

Switch.

Authentication is the process of determining who a user is and validating access to the Switch. The

Switch can authenticate users who try to log in based on user accounts configured on the Switch itself.

The Switch can also use an external authentication server to authenticate a large number of users.

Authorization is the process of determining what a user is allowed to do. Different user accounts may

have higher or lower privilege levels associated with them. For example, user A may have the right to

create new login accounts on the Switch but user B cannot. The Switch can authorize users based on

user accounts configured on the Switch itself or it can use an external server to authorize a large number

of users.

Accounting is the process of recording what a user is doing. The Switch can use an external server to

track when users log in, log out, and so on. Accounting can also record system related actions such as

boot up and shut down times of the Switch.

The external servers that perform authentication, authorization and accounting functions are known as

AAA servers. The Switch supports RADIUS (Remote Authentication Dial-In User Service, see RADIUS and

TACACS+ on page 225) as the external authentication and authorization server.

Figure 170 AAA Server

25.1.1 What You Can Do

• Use the AAA screen (Section 25.2 on page 225) to display the links to the screens where you can

enable authentication and authorization or both of them on the Switch.

• use the RADIUS Server Setup screen (Section 25.3 on page 226) to configure your RADIUS server

settings.

• Use the TACACS+ Server Setup screen (Section 25.4 on page 227) to configure your TACACS+

authentication settings.

• Use the AAA Setup screen (Section 25.5 on page 229) to configure authentication, authorization and

accounting settings, such as the methods used to authenticate users accessing the Switch and which

database the Switch should use first.

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25.1.2 What You Need to Know

Authentication is the process of determining who a user is and validating access to the Switch. The

Switch can authenticate users who try to log in based on user accounts configured on the Switch itself.

The Switch can also use an external authentication server to authenticate a large number of users.

Authorization is the process of determining what a user is allowed to do. Different user accounts may

have higher or lower privilege levels associated with them. For example, user A may have the right to

create new login accounts on the Switch but user B cannot. The Switch can authorize users based on

user accounts configured on the Switch itself or it can use an external server to authorize a large number

of users.

Accounting is the process of recording what a user is doing. The Switch can use an external server to

track when users log in, log out, execute commands and so on. Accounting can also record system

related actions such as boot up and shut down times of the Switch.

Local User Accounts

By storing user profiles locally on the Switch, your Switch is able to authenticate and authorize users

without interacting with a network AAA server. However, there is a limit on the number of users you may

authenticate in this way (See Section 44.4 on page 378).

RADIUS and TACACS+

RADIUS and TACACS+ are security protocols used to authenticate users by means of an external server

instead of (or in addition to) an internal device user database that is limited to the memory capacity of

the device. In essence, RADIUS and TACACS+ authentication both allow you to validate an unlimited

number of users from a central location.

The following table describes some key differences between RADIUS and TACACS+.

25.2 AAA Screens

The AAA screens allow you to enable authentication and authorization or both of them on the Switch.

First, configure your authentication server settings (RADIUS, TACACS+ or both) and then set up the

authentication priority, activate authorization.

Click Advanced Application > AAA in the navigation panel to display the screen as shown.

Table 94 RADIUS vs. TACACS+

RADIUS TACACS+

Transport

Protocol

UDP (User Datagram Protocol) TCP (Transmission Control Protocol)

Encryption Encrypts the password sent for

authentication.

All communication between the client (the Switch)

and the TACACS server is encrypted.

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Figure 171 Advanced Application > AAA

25.3 RADIUS Server Setup

Use this screen to configure your RADIUS server settings. See RADIUS and TACACS+ on page 225 for more

information on RADIUS servers and Section 25.6.2 on page 233 for RADIUS attributes utilized by the

authentication features on the Switch. Click on the RADIUS Server Setup link in the AAA screen to view

the screen as shown.

Figure 172 Advanced Application > AAA > RADIUS Server Setup

The following table describes the labels in this screen.

Table 95 Advanced Application > AAA > RADIUS Server Setup

LABEL DESCRIPTION

Authentication

Server

Use this section to configure your RADIUS authentication settings.

Mode This field is only valid if you configure multiple RADIUS servers.

Select index-priority and the Switch tries to authenticate with the first configured RADIUS server,

if the RADIUS server does not respond then the Switch tries to authenticate with the second

RADIUS server.

Select round-robin to alternate between the RADIUS servers that it sends authentication

requests to.

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25.4 TACACS+ Server Setup

Use this screen to configure your TACACS+ server settings. See RADIUS and TACACS+ on page 225 for

more information on TACACS+ servers. Click on the TACACS+ Server Setup link in the AAA screen to view

the screen as shown.

Timeout Specify the amount of time in seconds that the Switch waits for an authentication request

response from the RADIUS server.

If you are using index-priority for your authentication and you are using two RADIUS servers

then the timeout value is divided between the two RADIUS servers. For example, if you set the

timeout value to 30 seconds, then the Switch waits for a response from the first RADIUS server for

15 seconds and then tries the second RADIUS server.

Index This is a read-only number representing a RADIUS server entry.

IP Address Enter the IP address of an external RADIUS server in dotted decimal notation.

UDP Port The default port of a RADIUS server for authentication is 1812. You need not change this value

unless your network administrator instructs you to do so.

Shared Secret Specify a password (up to 32 alphanumeric characters) as the key to be shared between the

external RADIUS server and the Switch. This key is not sent over the network. This key must be the

same on the external RADIUS server and the Switch.

Delete Check this box if you want to remove an existing RADIUS server entry from the Switch. This entry

is deleted when you click Apply.

Accounting

Server

Use this section to configure your RADIUS accounting server settings.

Timeout Specify the amount of time in seconds that the Switch waits for an accounting request

response from the RADIUS accounting server.

Index This is a read-only number representing a RADIUS accounting server entry.

IP Address Enter the IP address of an external RADIUS accounting server in dotted decimal notation.

UDP Port The default port of a RADIUS accounting server for accounting is 1813. You need not change

this value unless your network administrator instructs you to do so.

Shared Secret Specify a password (up to 32 alphanumeric characters) as the key to be shared between the

external RADIUS accounting server and the Switch. This key is not sent over the network. This key

must be the same on the external RADIUS accounting server and the Switch.

Delete Check this box if you want to remove an existing RADIUS accounting server entry from the

Switch. This entry is deleted when you click Apply.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 95 Advanced Application > AAA > RADIUS Server Setup (continued)

LABEL DESCRIPTION

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Figure 173 Advanced Application > AAA > TACACS+ Server Setup

The following table describes the labels in this screen.

Table 96 Advanced Application > AAA > TACACS+ Server Setup

LABEL DESCRIPTION

Authentication

Server

Use this section to configure your TACACS+ authentication settings.

Mode This field is only valid if you configure multiple TACACS+ servers.

Select index-priority and the Switch tries to authenticate with the first configured TACACS+

server, if the TACACS+ server does not respond then the Switch tries to authenticate with the

second TACACS+ server.

Select round-robin to alternate between the TACACS+ servers that it sends authentication

requests to.

Timeout Specify the amount of time in seconds that the Switch waits for an authentication request

response from the TACACS+ server.

If you are using index-priority for your authentication and you are using two TACACS+ servers

then the timeout value is divided between the two TACACS+ servers. For example, if you set

the timeout value to 30 seconds, then the Switch waits for a response from the first TACACS+

server for 15 seconds and then tries the second TACACS+ server.

Index This is a read-only number representing a TACACS+ server entry.

IP Address Enter the IP address of an external TACACS+ server in dotted decimal notation.

TCP Port The default port of a TACACS+ server for authentication is 49. You need not change this value

unless your network administrator instructs you to do so.

Shared Secret Specify a password (up to 32 alphanumeric characters) as the key to be shared between the

external TACACS+ server and the Switch. This key is not sent over the network. This key must be

the same on the external TACACS+ server and the Switch.

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25.5 AAA Setup

Use this screen to configure authentication, authorization and accounting settings on the Switch. Click

on the AAA Setup link in the AAA screen to view the screen as shown.

Figure 174 Advanced Application > AAA > AAA Setup

Delete Check this box if you want to remove an existing TACACS+ server entry from the Switch. This

entry is deleted when you click Apply.

Accounting

Server

Use this section to configure your TACACS+ accounting settings.

Timeout Specify the amount of time in seconds that the Switch waits for an accounting request

response from the TACACS+ server.

Index This is a read-only number representing a TACACS+ accounting server entry.

IP Address Enter the IP address of an external TACACS+ accounting server in dotted decimal notation.

TCP Port The default port of a TACACS+ accounting server is 49. You need not change this value unless

your network administrator instructs you to do so.

Shared Secret Specify a password (up to 32 alphanumeric characters) as the key to be shared between the

external TACACS+ accounting server and the Switch. This key is not sent over the network. This

key must be the same on the external TACACS+ accounting server and the Switch.

Delete Check this box if you want to remove an existing TACACS+ accounting server entry from the

Switch. This entry is deleted when you click Apply.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 96 Advanced Application > AAA > TACACS+ Server Setup (continued)

LABEL DESCRIPTION

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The following table describes the labels in this screen.

Table 97 Advanced Application > AAA > AAA Setup

LABEL DESCRIPTION

Authentication Use this section to specify the methods used to authenticate users accessing the Switch.

Privilege Enable These fields specify which database the Switch should use (first, second and third) to

authenticate access privilege level for administrator accounts (users for Switch management).

Configure the access privilege of accounts via commands (see the Ethernet Switch CLI

Reference Guide) for local authentication. The TACACS+ and RADIUS are external servers.

Before you specify the priority, make sure you have set up the corresponding database

correctly first.

You can specify up to three methods for the Switch to authenticate the access privilege level

of administrators. The Switch checks the methods in the order you configure them (first Method

1, then Method 2 and finally Method 3). You must configure the settings in the Method 1 field. If

you want the Switch to check other sources for access privilege level specify them in Method 2

and Method 3 fields.

Select local to have the Switch check the access privilege configured for local authentication.

Select radius or tacacs+ to have the Switch check the access privilege via the external servers.

authenticate administrator accounts (users for Switch management).

Configure the local user accounts in the Access Control > Logins screen. The TACACS+ and

RADIUS are external servers. Before you specify the priority, make sure you have set up the

corresponding database correctly first.

You can specify up to three methods for the Switch to authenticate administrator accounts.

The Switch checks the methods in the order you configure them (first Method 1, then Method 2

and finally Method 3). You must configure the settings in the Method 1 field. If you want the

Switch to check other sources for administrator accounts, specify them in Method 2 and

Method 3 fields.

Select local to have the Switch check the administrator accounts configured in the Access

Control > Logins screen.

Select radius to have the Switch check the administrator accounts configured via the RADIUS

Server.

Select tacacs+ to have the Switch check the administrator accounts configured via the

TACACS+ Server.

Authorization Use this section to configure authorization settings on the Switch.

Type Set whether the Switch provides the following services to a user.

•Exec: Allow an administrator which logs in the Switch through Telnet or SSH to have different

access privilege level assigned via the external server.

•Dot1x: Allow an IEEE 802.1x client to have different bandwidth limit or VLAN ID assigned via

the external server.

Active Select this to activate authorization for a specified event types.

Console Select this to allow an administrator which logs in the Switch through the console port to have

different access privilege level assigned via the external server.

Method Select whether you want to use RADIUS or TACACS+ for authorization of specific types of

events.

RADIUS is the only method for IEEE 802.1x authorization.

Accounting Use this section to configure accounting settings on the Switch.

Update Period This is the amount of time in minutes before the Switch sends an update to the accounting

server. This is only valid if you select the start-stop option for the Exec or Dot1x entries.

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25.6 Technical Reference

This section provides technical background information on the topics discussed in this chapter.

25.6.1 Vendor Specific Attribute

RFC 2865 standard specifies a method for sending vendor-specific information between a RADIUS server

and a network access device (for example, the Switch). A company can create Vendor Specific

Attributes (VSAs) to expand the functionality of a RADIUS server.

The Switch supports VSAs that allow you to perform the following actions based on user authentication:

• Limit bandwidth on incoming or outgoing traffic for the port the user connects to.

• Assign account privilege levels (see the CLI Reference Guide for more information on account

privilege levels) for the authenticated user.

Type The Switch supports the following types of events to be sent to the accounting server(s):

•System - Configure the Switch to send information when the following system events occur:

system boots up, system shuts down, system accounting is enabled, system accounting is

disabled

•Exec - Configure the Switch to send information when an administrator logs in and logs out

via the console port, telnet or SSH.

•Dot1x - Configure the Switch to send information when an IEEE 802.1x client begins a session

(authenticates via the Switch), ends a session as well as interim updates of a session.

•Commands - Configure the Switch to send information when commands of specified

privilege level and higher are executed on the Switch.

Active Select this to activate accounting for a specified event types.

Broadcast Select this to have the Switch send accounting information to all configured accounting

servers at the same time.

If you don’t select this and you have two accounting servers set up, then the Switch sends

information to the first accounting server and if it doesn’t get a response from the accounting

server then it tries the second accounting server.

Mode The Switch supports two modes of recording login events. Select:

•start-stop - to have the Switch send information to the accounting server when a user

begins a session, during a user’s session (if it lasts past the Update Period), and when a user

ends a session.

•stop-only - to have the Switch send information to the accounting server only when a user

ends a session.

Method Select whether you want to use RADIUS or TACACS+ for accounting of specific types of events.

TACACS+ is the only method for recording Commands type of event.

Privilege This field is only configurable for Commands type of event. Select the threshold command

privilege level for which the Switch should send accounting information. The Switch will send

accounting information when commands at the level you specify and higher are executed on

the Switch.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 97 Advanced Application > AAA > AAA Setup (continued)

LABEL DESCRIPTION

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The VSAs are composed of the following:

•Vendor-ID: An identification number assigned to the company by the IANA (Internet Assigned

Numbers Authority). Zyxel’s vendor ID is 890.

•Vendor-Type: A vendor specified attribute, identifying the setting you want to modify.

•Vendor-data: A value you want to assign to the setting.

Note: Refer to the documentation that comes with your RADIUS server on how to configure

VSAs for users authenticating via the RADIUS server.

The following table describes the VSAs supported on the Switch. Note that these attributes only work

when you enable authorization (see Section 25.5 on page 229).

25.6.1.1 Tunnel Protocol Attribute

You can configure tunnel protocol attributes on the RADIUS server (refer to your RADIUS server

documentation) to assign a port on the Switch to a VLAN based on IEEE 802.1x authentication. The port

VLAN settings are fixed and untagged. This will also set the port’s VID. The following table describes the

Table 98 Supported VSAs

FUNCTION ATTRIBUTE

Ingress Bandwidth

Assignment Vendor-Id = 890

Vendor-Type = 1

Vendor-data = ingress rate (Kbps in decimal format)

Egress Bandwidth

Assignment Vendor-Id = 890

Vendor-Type = 2

Vendor-data = egress rate (Kbps in decimal format)

Privilege Assignment Vendor-ID = 890

Vendor-Type = 3

Vendor-Data = "shell:priv-lvl=N"

Vendor-ID = 9 (CISCO)

Vendor-Type = 1 (CISCO-AVPAIR)

Vendor-Data = "shell:priv-lvl=N"

where N is a privilege level (from 0 to 14).

Note: If you set the privilege level of a login account differently on the RADIUS

server(s) and the Switch, the user is assigned a privilege level from the

database (RADIUS or local) the Switch uses first for user authentication.

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values you need to configure. Note that these attributes only work when you enable authorization (see

Section 25.5 on page 229).

25.6.2 Supported RADIUS Attributes

Remote Authentication Dial-In User Service (RADIUS) attributes are data used to define specific

authentication elements in a user profile, which is stored on the RADIUS server. This appendix lists the

RADIUS attributes supported by the Switch.

Refer to RFC 2865 for more information about RADIUS attributes used for authentication.

This section lists the attributes used by authentication functions on the Switch. In cases where the

attribute has a specific format associated with it, the format is specified.

25.6.3 Attributes Used for Authentication

The following sections list the attributes sent from the Switch to the RADIUS server when performing

authentication.

25.6.3.1 Attributes Used for Authenticating Privilege Access

User-Name

- The format of the User-Name attribute is $enab#$, where # is the privilege level (1-14).

User-Password

NAS-Identifier

NAS-IP-Address

25.6.3.2 Attributes Used to Login Users

User-Name

User-Password

NAS-Identifier

NAS-IP-Address

Table 99 Supported Tunnel Protocol Attribute

FUNCTION ATTRIBUTE

VLAN Assignment Tunnel-Type = VLAN(13)

Tunnel-Medium-Type = 802(6)

Tunnel-Private-Group-ID = VLAN ID

Note: You must also create a VLAN with the specified VID on the Switch.

Note: The bolded values in this table are fixed values as defined in RFC 3580.

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25.6.3.3 Attributes Used by the IEEE 802.1x Authentication

User-Name

NAS-Identifier

NAS-IP-Address

NAS-Port

NAS-Port-Type

- This value is set to Ethernet(15) on the Switch.

Calling-Station-Id

Frame-MTU

EAP-Message

State

Message-Authenticator

25.6.4 Attributes Used for Accounting

The following sections list the attributes sent from the Switch to the RADIUS server when performing

authentication.

25.6.4.1 Attributes Used for Accounting System Events

NAS-IP-Address

NAS-Identifier

Acct-Status-Type

Acct-Session-ID

- The format of Acct-Session-Id is date+time+8-digit sequential number, for example,

2007041917210300000001. (date: 2007/04/19, time: 17:21:03, serial number: 00000001)

Acct-Delay-Time

25.6.4.2 Attributes Used for Accounting Exec Events

The attributes are listed in the following table along with the time that they are sent (the difference

between Console and Telnet/SSH Exec events is that the Telnet/SSH events utilize the Calling-Station-Id

attribute):

Table 100 RADIUS Attributes - Exec Events via Console

ATTRIBUTE START INTERIM-UPDATE STOP

User-Name  

NAS-Identifier  

NAS-IP-Address  

Service-Type  

Acct-Status-Type  

Acct-Delay-Time  

Acct-Session-Id  

Acct-Authentic  

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25.6.4.3 Attributes Used for Accounting IEEE 802.1x Events

The attributes are listed in the following table along with the time of the session they are sent:

Acct-Session-Time 

Acct-Terminate-Cause 

Table 101 RADIUS Attributes - Exec Events via Telnet/SSH

ATTRIBUTE START INTERIM-UPDATE STOP

User-Name  

NAS-Identifier  

NAS-IP-Address  

Service-Type  

Calling-Station-Id  

Acct-Status-Type  

Acct-Delay-Time  

Acct-Session-Id  

Acct-Authentic  

Acct-Session-Time 

Acct-Terminate-Cause 

Table 100 RADIUS Attributes - Exec Events via Console

ATTRIBUTE START INTERIM-UPDATE STOP

Table 102 RADIUS Attributes - Exec Events via Console

ATTRIBUTE START INTERIM-UPDATE STOP

User-Name  

NAS-IP-Address  

NAS-Port  

Class  

Called-Station-Id  

Calling-Station-Id  

NAS-Identifier  

NAS-Port-Type  

Acct-Status-Type  

Acct-Delay-Time  

Acct-Session-Id  

Acct-Authentic  

Acct-Input-Octets 

Acct-Output-Octets 

Acct-Session-Time 

Acct-Input-Packets 

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Acct-Output-Packets 

Acct-Terminate-Cause 

Acct-Input-Gigawords 

Acct-Output-Gigawords 

Table 102 RADIUS Attributes - Exec Events via Console

ATTRIBUTE START INTERIM-UPDATE STOP

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CHAPTER 26

IP Source Guard

26.1 IP Source Guard Overview

IP source guard uses a binding table to distinguish between authorized and unauthorized DHCP and

ARP packets in your network. A binding contains these key attributes:

• MAC address

• VLAN ID

• IP address

• Port number

When the Switch receives a DHCP or ARP packet, it looks up the appropriate MAC address, VLAN ID, IP

address, and port number in the binding table. If there is a binding, the Switch forwards the packet. If

there is not a binding, the Switch discards the packet.

The Switch builds the binding table by snooping DHCP packets (dynamic bindings) and from information

provided manually by administrators (static bindings).

IP source guard consists of the following features:

• Static bindings. Use this to create static bindings in the binding table.

• DHCP snooping. Use this to filter unauthorized DHCP packets on the network and to build the binding

table dynamically.

• ARP inspection. Use this to filter unauthorized ARP packets on the network.

If you want to use dynamic bindings to filter unauthorized ARP packets (typical implementation), you

have to enable DHCP snooping before you enable ARP inspection.

26.1.1 What You Can Do

• Use the IP Source Guard screen (Section 26.2 on page 239) to look at the current bindings for DHCP

snooping and ARP inspection.

• Use the IP Source Guard Static Binding screen (Section 26.4 on page 240) to manage static bindings

for DHCP snooping and ARP inspection.

• Use the DHCP Snooping screen (Section 26.5 on page 242) to look at various statistics about the DHCP

snooping database.

• Use this DHCP Snooping Configure screen (Section 26.6 on page 245) to enable DHCP snooping on

the Switch (not on specific VLAN), specify the VLAN where the default DHCP server is located, and

configure the DHCP snooping database.

• Use the DHCP Snooping Port Configure screen (Section 26.6.1 on page 246) to specify whether ports

are trusted or untrusted ports for DHCP snooping.

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• Use the DHCP Snooping VLAN Configure screen (Section 26.6.2 on page 247) to enable DHCP

snooping on each VLAN and to specify whether or not the Switch adds DHCP relay agent option 82

information to DHCP requests that the Switch relays to a DHCP server for each VLAN.

• Use the DHCP Snooping VLAN Port Configure screen (Section 26.6.3 on page 248) to apply a different

DHCP option 82 profile to certain ports in a VLAN.

• Use the ARP Inspection Status screen (Section 26.7 on page 249) to look at the current list of MAC

address filters that were created because the Switch identified an unauthorized ARP packet.

• Use the ARP Inspection VLAN Status screen (Section 26.7.1 on page 250) to look at various statistics

about ARP packets in each VLAN.

• Use the ARP Inspection Log Status screen (Section 26.7.2 on page 251) to look at log messages that

were generated by ARP packets and that have not been sent to the syslog server yet.

• Use the ARP Inspection Configure screen (Section 26.8 on page 252) to enable ARP inspection on the

Switch. You can also configure the length of time the Switch stores records of discarded ARP packets

and global settings for the ARP inspection log.

• Use the ARP Inspection Port Configure screen (Section 26.8.1 on page 253) to specify whether ports

are trusted or untrusted ports for ARP inspection.

• Use the ARP Inspection VLAN Configur e screen (Section 26.8.2 on page 255) to enable ARP inspection

on each VLAN and to specify when the Switch generates log messages for receiving ARP packets

from each VLAN.

• Use the Advanced Application > IP Source Guard > IPv6 Source Binding Status screen (Section 26.10

on page 256) to look at the current IPv6 dynamic and static bindings and to remove dynamic

bindings based on IPv6 address and/or IPv6 prefix.

• Use the Advanced Application > IP Source Guard > IPv6 Static Bindin g Setup screen (Section 26.11 on

page 257) to manually create an IPv6 source guard binding table and manage IPv6 static bindings.

• Use the Advanced Application > IP Source Guard > IPv6 Source Guard Policy Setup screen (Section

26.12 on page 258) to have IPv6 source guard forward valid IPv6 addresses and/or IPv6 prefixes that

are stored in the binding table and allow or block data traffic from all link-local addresses.

• Use the Advanced Application > IP Source Guard > IPv6 Source Guard Port Setup screen (Section

26.13 on page 259) to apply configured IPv6 source guard policies to the ports you specify.

• Use the Advanced Application > IP Source Guard > IPv6 Snooping Policy Setup screen (Section 26.14

on page 260) to dynamically create an IPv6 source guard binding table using a DHCPv6 snooping

policy. A DHCPv6 snooping policy lets the Switch sniff DHCPv6 packets sent from a DHCPv6 server to a

DHCPv6 client when it is assigning an IPv6 address.

• Use the Advanced Application > IP Source Guard > IPv6 Snooping VLAN Setup screen (Section 26.15

on page 261) to enable a DHCPv6 snooping policy on a specific VLAN interface.

• Use the Advanced Application > IP Source Guard > IPv6 DHCP Trust Setup screen (Section 26.16 on

page 262) to specify which ports are trusted and untrusted for DHCP snooping.

26.1.2 What You Need to Know

The Switch builds the binding table by snooping DHCP packets (dynamic bindings) and from information

provided manually by administrators (static bindings).

IP source guard consists of the following features:

• Static bindings. Use this to create static bindings in the binding table.

• DHCP snooping. Use this to filter unauthorized DHCP packets on the network and to build the binding

table dynamically.

• ARP inspection. Use this to filter unauthorized ARP packets on the network.

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If you want to use dynamic bindings to filter unauthorized ARP packets (typical implementation), you

have to enable DHCP snooping before you enable ARP inspection.

26.2 IP Source Guard

Use this screen to look at the current bindings for DHCP snooping and ARP inspection. Bindings are used

by DHCP snooping and ARP inspection to distinguish between authorized and unauthorized packets in

the network. The Switch learns the bindings by snooping DHCP packets (dynamic bindings) and from

information provided manually by administrators (static bindings). To open this screen, click Advanced

Application > IP Source Guard.

Figure 175 IP Source Guard

The following table describes the labels in this screen.

Table 103 IP Source Guard

LABEL DESCRIPTION

IPv4 Source Guard

Setup

Click the link to open screens where you can view and manage static bindings, configure

DHCP snooping or ARP inspection and look at various statistics.

IPv6 Source Binding

Status

Click the link to open a screen where you can view the current IPv6 dynamic and static

bindings or remove dynamic bindings based on IPv6 address and/or IPv6 prefix.

IPv6 Static Binding

Setup

Click the link to open a screen where you can manually create IPv6 source guard static

binding entries.

IPv6 Source Guard

Policy Setup

Click the link to open a screen where you can define policies to have IPv6 source guard

forward valid addresses and/or prefixes and allow or block data traffic from all link-local

addresses.

IPv6 Source Guard

Port Setup

Click the link to open a screen where you can apply the configured IPv6 source guard

policy to a port.

IPv6 Snooping Policy

Setup

Click the link to open a screen where you can set up DHCPv6 snooping policies for the

binding table.

IPv6 Snooping VLAN

Setup

Click the link to open a screen where you can enable a DHCPv6 snooping policy on a

specific VLAN interface.

IPv6 DHCP Trust Setup Click the link to open a screen where you can specify which ports are trusted for DHCPv6

snooping.

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26.3 IPv4 Source Guard Setup

Use this screen to look at the current bindings for DHCP snooping and ARP inspection. Bindings are used

by DHCP snooping and ARP inspection to distinguish between authorized and unauthorized packets in

the network. The Switch learns the bindings by snooping DHCP packets (dynamic bindings) and from

information provided manually by administrators (static bindings). To open this screen, click Advanced

Application > IP Source Guard > IPv4 Source Guard Setup.

Figure 176 Advanced Application > IP Source Guard > IPv4 Source Guard Setup

The following table describes the labels in this screen.

26.4 IPv4 Source Guard Static Binding

Use this screen to manage static bindings for DHCP snooping and ARP inspection. Static bindings are

uniquely identified by the MAC address and VLAN ID. Each MAC address and VLAN ID can only be in

one static binding. If you try to create a static binding with the same MAC address and VLAN ID as an

existing static binding, the new static binding replaces the original one. To open this screen, click

Advanced Application > IP Source Guard > IPv4 Source Guard Setup > Static Binding.

Table 104 Advanced Application > IP Source Guard > IPv4 Source Guard Setup

LABEL DESCRIPTION

Index This field displays a sequential number for each binding.

IP Address This field displays the IP address assigned to the MAC address in the binding.

VLAN This field displays the source VLAN ID in the binding.

MAC Address This field displays the source MAC address in the binding.

Port This field displays the port number in the binding. If this field is blank, the binding applies to all

ports.

Lease This field displays how many days, hours, minutes, and seconds the binding is valid; for

example, 2d3h4m5s means the binding is still valid for 2 days, 3 hours, 4 minutes, and 5

seconds. This field displays infinity if the binding is always valid (for example, a static binding).

Type This field displays how the Switch learned the binding.

static: This binding was learned from information provided manually by an administrator.

dhcp-snooping: This binding was learned by snooping DHCP packets.

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Figure 177 IP Source Guard > IPv4 Source Guard Setup > Static Binding

The following table describes the labels in this screen.

Table 105 IP Source Guard > IPv4 Source Guard Setup > Static Binding

LABEL DESCRIPTION

ARP Freeze ARP Freeze allows you to automatically create static bindings from the current ARP entries

(either dynamically learned or static ARP entries) until the Switch’s binding table is full.

Note: The ARP learning mode should be set to ARP-Request in the IP Application >

ARP Setup > ARP Learning screen before you use the ARP Freeze feature.

Condition All - Select this and click ARP Freeze to have the Switch automatically add all the current ARP

entries to the static bindings table.

Port List - Select this and enter the number of the port(s) (separated by a comma).

ARP entries learned on the specified port(s) are added to the static bindings table after you

click ARP Freeze.

VLAN List - Select this and enter the ID number of the VLAN(s) (separated by a comma). ARP

entries for the specified VLAN(s) are added to the static bindings table after you click ARP

Freeze.

Static Binding

IP Address Enter the IP address assigned to the MAC address in the binding.

VLAN Enter the source VLAN ID in the binding.

MAC Address Enter the source MAC address in the binding. If this binding applies to all MAC addresses,

select Any.

Port Specify the port(s) in the binding. If this binding has one port, select the first radio button and

enter the port number in the field to the right. If this binding applies to all ports, select Any.

Add Click this to create a new entry or to update an existing one.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your

changes to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values above based on the last selected static binding or, if not

applicable, to clear the fields above.

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26.5 DHCP Snooping

Use this screen to look at various statistics about the DHCP snooping database. To open this screen, click

Advanced Application > IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping.

Clear Click Clear to reset the fields to the factory defaults.

Index This field displays a sequential number for each binding. Click on an index number to view

more details or change the settings.

IP Address This field displays the IP address assigned to the MAC address in the binding.

VLAN This field displays the source VLAN ID in the binding.

MAC Address This field displays the source MAC address in the binding.

Port This field displays the port number.

Lease This field displays how long the binding is valid.

Type This field displays how the Switch learned the binding.

static: This binding was learned from information provided manually by an administrator.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Select the entry(ies) that you want to remove, then click the Delete button to remove the

selected entry(ies) from the table.

Cancel Click this to clear the check boxes above.

Table 105 IP Source Guard > IPv4 Source Guard Setup > Static Binding (continued)

LABEL DESCRIPTION

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Figure 178 IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping

The following table describes the labels in this screen.

Table 106 IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping

LABEL DESCRIPTION

Database Status

This section displays the current settings for the DHCP snooping database. You can

configure them in the DHCP Snooping Configure screen. See Section 26.6 on page 245.

Agent URL This field displays the location of the DHCP snooping database.

Write delay timer This field displays how long (in seconds) the Switch tries to complete a specific update in the

DHCP snooping database before it gives up.

Abort timer This field displays how long (in seconds) the Switch waits to update the DHCP snooping

database after the current bindings change.

This section displays information about the current update and the next update of the DHCP

snooping database.

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Agent running This field displays the status of the current update or access of the DHCP snooping

database.

none: The Switch is not accessing the DHCP snooping database.

read: The Switch is loading dynamic bindings from the DHCP snooping database.

write: The Switch is updating the DHCP snooping database.

Delay timer expiry This field displays how much longer (in seconds) the Switch tries to complete the current

update before it gives up. It displays Not Running if the Switch is not updating the DHCP

snooping database right now.

Abort timer expiry This field displays when (in seconds) the Switch is going to update the DHCP snooping

database again. It displays Not Running if the current bindings have not changed since the

last update.

This section displays information about the last time the Switch updated the DHCP snooping

database.

Last succeeded

time

This field displays the last time the Switch updated the DHCP snooping database

successfully.

Last failed time This field displays the last time the Switch updated the DHCP snooping database

unsuccessfully.

Last failed reason This field displays the reason the Switch updated the DHCP snooping database

unsuccessfully.

This section displays historical information about the number of times the Switch successfully

or unsuccessfully read or updated the DHCP snooping database.

Total attempts This field displays the number of times the Switch has tried to access the DHCP snooping

database for any reason.

Startup failures This field displays the number of times the Switch could not create or read the DHCP

snooping database when the Switch started up or a new URL is configured for the DHCP

snooping database.

Successful transfers This field displays the number of times the Switch read bindings from or updated the bindings

in the DHCP snooping database successfully.

Failed transfers This field displays the number of times the Switch was unable to read bindings from or

update the bindings in the DHCP snooping database.

Successful reads This field displays the number of times the Switch read bindings from the DHCP snooping

database successfully.

Failed reads This field displays the number of times the Switch was unable to read bindings from the

DHCP snooping database.

Successful writes This field displays the number of times the Switch updated the bindings in the DHCP

snooping database successfully.

Failed writes This field displays the number of times the Switch was unable to update the bindings in the

DHCP snooping database.

Database detail

First successful

access

This field displays the first time the Switch accessed the DHCP snooping database for any

reason.

Last ignored

bindings counters

This section displays the number of times and the reasons the Switch ignored bindings the

last time it read bindings from the DHCP binding database. You can clear these counters by

restarting the Switch or using CLI commands. See the Ethernet Switch CLI Reference Guide.

Binding collisions This field displays the number of bindings the Switch ignored because the Switch already

had a binding with the same MAC address and VLAN ID.

Invalid interfaces This field displays the number of bindings the Switch ignored because the port number was

a trusted interface or does not exist anymore.

Table 106 IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping (continued)

LABEL DESCRIPTION

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26.6 DHCP Snooping Configure

Use this screen to enable DHCP snooping on the Switch (not on specific VLAN), specify the VLAN where

the default DHCP server is located, and configure the DHCP snooping database. The DHCP snooping

database stores the current bindings on a secure, external TFTP server so that they are still available after

a restart. To open this screen, click Advanced Application > IP Source Guard > IPv4 Sou rce Guard Setup

> DHCP Snooping > Configure.

Figure 179 IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping > Configure

Parse failures This field displays the number of bindings the Switch ignored because the Switch was unable

to understand the binding in the DHCP binding database.

Expired leases This field displays the number of bindings the Switch ignored because the lease time had

already expired.

Unsupported vlans This field displays the number of bindings the Switch ignored because the VLAN ID does not

exist anymore.

Last ignored time This field displays the last time the Switch ignored any bindings for any reason from the DHCP

binding database.

Total ignored

bindings counters

This section displays the reasons the Switch has ignored bindings any time it read bindings

from the DHCP binding database. You can clear these counters by restarting the Switch or

using CLI commands. See the Ethernet Switch CLI Reference Guide.

Binding collisions This field displays the number of bindings the Switch has ignored because the Switch already

had a binding with the same MAC address and VLAN ID.

Invalid interfaces This field displays the number of bindings the Switch has ignored because the port number

was a trusted interface or does not exist anymore.

Parse failures This field displays the number of bindings the Switch has ignored because the Switch was

unable to understand the binding in the DHCP binding database.

Expired leases This field displays the number of bindings the Switch has ignored because the lease time

had already expired.

Unsupported vlans This field displays the number of bindings the Switch has ignored because the VLAN ID does

not exist anymore.

Table 106 IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping (continued)

LABEL DESCRIPTION

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The following table describes the labels in this screen.

26.6.1 DHCP Snooping Port Configure

Use this screen to specify whether ports are trusted or untrusted ports for DHCP snooping.

Note: The Switch will drop all DHCP requests if you enable DHCP snooping and there are no

trusted ports.

You can also specify the maximum number for DHCP packets that each port (trusted or untrusted) can

receive each second. To open this screen, click Advanced Application > IP Source Guard > IPv4 Sou rce

Guard Setup > DHCP Snooping > Configure > Port.

Table 107 IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping > Configure

LABEL DESCRIPTION

Active Select this to enable DHCP snooping on the Switch. You still have to enable DHCP snooping

on specific VLAN and specify trusted ports.

Note: The Switch will drop all DHCP requests if you enable DHCP snooping and

there are no trusted ports.

DHCP Vlan Select a VLAN ID if you want the Switch to forward DHCP packets to DHCP servers on a

specific VLAN.

Note: You have to enable DHCP snooping on the DHCP VLAN too.

You can select an option 82 profile in the DHCP Snooping VLAN Configure screen (Section

26.6.2 on page 247) to help the DHCP servers distinguish between DHCP requests from

different VLAN.

Select Disable if you do not want the Switch to forward DHCP packets to a specific VLAN.

Database If Timeout interval is greater than Write delay interval, it is possible that the next update is

scheduled to occur before the current update has finished successfully or timed out. In this

case, the Switch waits to start the next update until it completes the current one.

Agent URL Enter the location of the DHCP snooping database. The location should be expressed like

this: tftp://{domain name or IP address}/directory, if applicable/file name; for example,

tftp://192.168.10.1/database.txt.

Timeout interval Enter how long (10-65535 seconds) the Switch tries to complete a specific update in the

DHCP snooping database before it gives up.

Write delay

interval Enter how long (10-65535 seconds) the Switch waits to update the DHCP snooping

database the first time the current bindings change after an update. Once the next

update is scheduled, additional changes in current bindings are automatically included in

the next update.

Renew DHCP

Snooping URL Enter the location of a DHCP snooping database, and click Renew if you want the Switch to

load it. You can use this to load dynamic bindings from a different DHCP snooping

database than the one specified in Agent URL.

When the Switch loads dynamic bindings from a DHCP snooping database, it does not

discard the current dynamic bindings first. If there is a conflict, the Switch keeps the

dynamic binding in volatile memory and updates the Binding collisions counter in the DHCP

Snooping screen (Section 26.5 on page 242).

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values in this screen to their last-saved values.

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Figure 180 IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping > Configure> Port

The following table describes the labels in this screen.

26.6.2 DHCP Snooping VLAN Configure

Use this screen to enable DHCP snooping on each VLAN and to specify whether or not the Switch adds

DHCP relay agent option 82 information (Chapter 41 on page 343) to DHCP requests that the Switch

relays to a DHCP server for each VLAN. To open this screen, click Advanced Application > IP Source

Guard > IPv4 Source Guard Setup > DHCP Snooping > Configure > VLAN.

Table 108 IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping > Configure > Port

LABEL DESCRIPTION

Port This field displays the port number.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to

set the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Server Trusted state Select whether this port is a trusted port (Trusted) or an untrusted port (Untrusted).

Trusted ports are connected to DHCP servers or other switches, and the Switch discards

DHCP packets from trusted ports only if the rate at which DHCP packets arrive is too high.

Untrusted ports are connected to subscribers, and the Switch discards DHCP packets from

untrusted ports in the following situations:

• The packet is a DHCP server packet (for example, OFFER, ACK, or NACK).

• The source MAC address and source IP address in the packet do not match any of the

current bindings.

• The packet is a RELEASE or DECLINE packet, and the source MAC address and source

port do not match any of the current bindings.

• The rate at which DHCP packets arrive is too high.

Rate (pps) Specify the maximum number for DHCP packets (1-2048) that the Switch receives from

each port each second. The Switch discards any additional DHCP packets. Enter 0 to

disable this limit, which is recommended for trusted ports.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values in this screen to their last-saved values.

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Figure 181 IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping > Configure > VLAN

The following table describes the labels in this screen.

26.6.3 DHCP Snooping VLAN Port Configure

Use this screen to apply a different DHCP option 82 profile to certain ports in a VLAN. To open this screen,

click Advanced Application > IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping > Configure

> VLAN > Port.

Figure 182 IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping > Configure > VLAN > Port

Table 109 IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping > Configure > VLAN

LABEL DESCRIPTION

VLAN Search by VID Use a comma (,) to separate individual VLANs or a dash (-) to indicates a range of VLANs. For

example, “3,4” or “3-9”.

Search Click this to display the specified range of VLANs in the section below.

VID This field displays the VLAN ID of each VLAN in the range specified above. If you configure

the * VLAN, the settings are applied to all VLANs.

Enabled Select Yes to enable DHCP snooping on the VLAN. You still have to enable DHCP snooping

on the Switch and specify trusted ports.

Note: The Switch will drop all DHCP requests if you enable DHCP snooping and

there are no trusted ports.

Option 82 Profile Select a pre-defined DHCP option 82 profile that the Switch applies to all ports in the

specified VLAN(s). The Switch adds the information (such as slot number, port number, VLAN

ID and/or system name) specified in the profile to DHCP requests that it broadcasts to the

DHCP VLAN, if specified, or VLAN. You can specify the DHCP VLAN in the DHCP Snooping

Configure screen (see Section 26.6 on page 245).

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values in this screen to their last-saved values.

Change Pages Click Previous or Next to show the previous/next screen if all status information cannot be

seen in one screen.

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The following table describes the labels in this screen.

26.7 ARP Inspection Status

Use this screen to look at the current list of MAC address filters that were created because the Switch

identified an unauthorized ARP packet. When the Switch identifies an unauthorized ARP packet, it

automatically creates a MAC address filter to block traffic from the source MAC address and source

VLAN ID of the unauthorized ARP packet. To open this screen, click Advanced Application > IP Source

Guard > IPv4 Source Guard Setup > ARP Inspection.

Figure 183 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection Status

Table 110 IP Source Guard > IPv4 Source Guard Setup > DHCP Snooping > Configure > VLAN > Port

LABEL DESCRIPTION

VID Enter the ID number of the VLAN you want to configure here.

Port Enter the number of port(s) to which you want to apply the specified DHCP option 82 profile.

You can enter multiple ports separated by (no space) comma (,) or hyphen (-) for a range.

For example, enter “3-5” for ports 3, 4, and 5. Enter “3,5,7” for ports 3, 5, and 7.

Option 82 Profile Select a pre-defined DHCP option 82 profile that the Switch applies to the specified port(s) in

this VLAN. The Switch adds the information (such as slot number, port number, VLAN ID and/

or system name) specified in the profile to DHCP requests that it broadcasts to the DHCP

VLAN, if specified, or VLAN. You can specify the DHCP VLAN in the DHCP Snooping Configure

screen (see Section 26.6 on page 245).

Note: The profile you select here has priority over the one you select in the DHCP

Snooping > Configure > VLAN screen.

Add Click this to create a new entry or to update an existing one.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it

is turned off or loses power, so use the Save link on the top navigation panel to save your

changes to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values above based on the last selected entry or, if not applicable, to

clear the fields above.

Clear Click Clear to reset the fields to the factory defaults.

Index This field displays a sequential number for each entry. Click an index number to change the

settings.

VID This field displays the VLAN to which the port(s) belongs.

Port This field displays the port(s) to which the Switch applies the settings.

Profile Name This field displays the DHCP option 82 profile that the Switch applies to the port(s).

Delete Select the entry(ies) that you want to remove in the Delete column, and then click the Delete

button to remove the selected entry(ies) from the table.

Cancel Click this to clear the Delete check boxes above.

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The following table describes the labels in this screen.

26.7.1 ARP Inspection VLAN Status

Use this screen to look at various statistics about ARP packets in each VLAN. To open this screen, click

Advanced Application > IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > VLAN Status.

Figure 184 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > VLAN Status

The following table describes the labels in this screen.

Table 111 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection Status

LABEL DESCRIPTION

Total number of

filters

This field displays the current number of MAC address filters that were created because the

Switch identified unauthorized ARP packets.

Index This field displays a sequential number for each MAC address filter.

MAC Address This field displays the source MAC address in the MAC address filter.

VID This field displays the source VLAN ID in the MAC address filter.

Port This field displays the source port of the discarded ARP packet.

Expiry (sec) This field displays how long (in seconds) the MAC address filter remains in the Switch. You

can also delete the record manually (Delete).

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Click this to remove the selected entries.

Cancel Click this to clear the Delete check boxes above.

Change Pages Click Previous Page or Next Page to show the previous/next screen if all status information

cannot be seen in one screen.

Table 112 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > VLAN Status

LABEL DESCRIPTION

VLAN Search by VID Use a comma (,) to separate individual VLANs or a dash (-) to indicates a range of VLANs.

For example, “3,4” or “3-9”.

Search Click this to display the specified range of VLANs in the section below.

VID This field displays the VLAN ID of each VLAN in the range specified above.

Received This field displays the total number of ARP packets received from the VLAN since the Switch

last restarted.

Request This field displays the total number of ARP Request packets received from the VLAN since

the Switch last restarted.

Reply This field displays the total number of ARP Reply packets received from the VLAN since the

Switch last restarted.

Forwarded This field displays the total number of ARP packets the Switch forwarded for the VLAN since

the Switch last restarted.

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26.7.2 ARP Inspection Log Status

Use this screen to look at log messages that were generated by ARP packets and that have not been

sent to the syslog server yet. To open this screen, click Advanced Application > IP Source Guard > IPv4

Source Guard Setup > ARP Inspection > Log Status.

Figure 185 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > Log Status

The following table describes the labels in this screen.

Dropped This field displays the total number of ARP packets the Switch discarded for the VLAN since

the Switch last restarted.

Change Pages Click Previous Page or Next Pa ge to show the previous/next screen if all status information

cannot be seen in one screen.

Table 112 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > VLAN Status

LABEL DESCRIPTION

Table 113 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > Log Status

LABEL DESCRIPTION

Clearing log status table Click Apply to remove all the log messages that were generated by ARP packets and

that have not been sent to the syslog server yet.

Total number of logs This field displays the number of log messages that were generated by ARP packets

and that have not been sent to the syslog server yet. If one or more log messages are

dropped due to unavailable buffer, there is an entry called overflow with the current

number of dropped log messages.

Index This field displays a sequential number for each log message.

Port This field displays the source port of the ARP packet.

VID This field displays the source VLAN ID of the ARP packet.

Sender MAC This field displays the source MAC address of the ARP packet.

Sender IP This field displays the source IP address of the ARP packet.

Num Pkts This field displays the number of ARP packets that were consolidated into this log

message. The Switch consolidates identical log messages generated by ARP packets

in the log consolidation interval into one log message. You can configure this interval in

the ARP Inspection Configure screen. See Section 26.8 on page 252.

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26.8 ARP Inspection Configure

Use this screen to enable ARP inspection on the Switch. You can also configure the length of time the

Switch stores records of discarded ARP packets and global settings for the ARP inspection log. To open

this screen, click Advanced Application > IP Source Guard > IPv4 Sour ce Guard Setup > ARP Inspection >

Configure.

Figure 186 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > Configure

The following table describes the labels in this screen.

Reason This field displays the reason the log message was generated.

dhcp deny: An ARP packet was discarded because it violated a dynamic binding with

the same MAC address and VLAN ID.

static deny: An ARP packet was discarded because it violated a static binding with the

same MAC address and VLAN ID.

deny: An ARP packet was discarded because there were no bindings with the same

MAC address and VLAN ID.

dhcp permit: An ARP packet was forwarded because it matched a dynamic binding.

static permit: An ARP packet was forwarded because it matched a static binding.

In the ARP Inspection VLAN Configure screen, you can configure the Switch to

generate log messages when ARP packets are discarded or forwarded based on the

VLAN ID of the ARP packet. See Section 26.8.2 on page 255.

Time This field displays when the log message was generated.

Table 113 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > Log Status (continued)

LABEL DESCRIPTION

Table 114 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > Configure

LABEL DESCRIPTION

Active Select this to enable ARP inspection on the Switch. You still have to enable ARP inspection

on specific VLAN and specify trusted ports.

Filter Aging Time

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26.8.1 ARP Inspection Port Configure

Use this screen to specify whether ports are trusted or untrusted ports for ARP inspection. You can also

specify the maximum rate at which the Switch receives ARP packets on each untrusted port. To open

this screen, click Advanced Application > IP Source Guard > IPv4 Sour ce Guard Setup > ARP Inspection >

Configure > Port.

Filter aging time This setting has no effect on existing MAC address filters.

Enter how long (1-2147483647 seconds) the MAC address filter remains in the Switch after

the Switch identifies an unauthorized ARP packet. The Switch automatically deletes the

MAC address filter afterwards. Type 0 if you want the MAC address filter to be permanent.

Log Profile

Log buffer size Enter the maximum number (1-1024) of log messages that were generated by ARP packets

and have not been sent to the syslog server yet. Make sure this number is appropriate for

the specified Syslog rate and Log interval.

If the number of log messages in the Switch exceeds this number, the Switch stops recording

log messages and simply starts counting the number of entries that were dropped due to

unavailable buffer. Click Clea ring log status tab le in the ARP Inspection Log Status screen to

clear the log and reset this counter. See Section 26.7.2 on page 251.

Syslog rate Type the maximum number of syslog messages the Switch can send to the syslog server in

one batch. This number is expressed as a rate because the batch frequency is determined

by the Log Interval. You must configure the syslog server (Chapter 47 on page 395) to use

this. Enter 0 if you do not want the Switch to send log messages generated by ARP packets

to the syslog server.

The relationship between Syslog rate and Log interval is illustrated in the following examples:

• 4 invalid ARP packets per second, Syslog rate is 5, Log interval is 1: the Switch sends 4

syslog messages every second.

• 6 invalid ARP packets per second, Syslog rate is 5, Log interval is 2: the Switch sends 5

syslog messages every 2 seconds.

Log interval Type how often (1-86400 seconds) the Switch sends a batch of syslog messages to the syslog

server. Enter 0 if you want the Switch to send syslog messages immediately. See Syslog rate

for an example of the relationship between Syslog rate and Log interval.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values in this screen to their last-saved values.

Table 114 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > Configure (continued)

LABEL DESCRIPTION

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Figure 187 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > Configure > Port

The following table describes the labels in this screen.

Table 115 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > Configure > Port

LABEL DESCRIPTION

Port This field displays the port number.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first

to set the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make

them.

Trusted State Select whether this port is a trusted port (Trusted) or an untrusted port (Untrusted).

The Switch does not discard ARP packets on trusted ports for any reason.

The Switch discards ARP packets on untrusted ports in the following situations:

• The sender’s information in the ARP packet does not match any of the current

bindings.

• The rate at which ARP packets arrive is too high. You can specify the maximum rate

at which ARP packets can arrive on untrusted ports.

Limit Rate and Burst Interval settings have no effect on trusted ports.

Rate (pps) Specify the maximum rate (1-2048 packets per second) at which the Switch receives ARP

packets from each port. The Switch discards any additional ARP packets. Enter 0 to

disable this limit.

Burst interval (seconds) The burst interval is the length of time over which the rate of ARP packets is monitored for

each port. For example, if the Rate is 15 pps and the burst interval is 1 second, then the

Switch accepts a maximum of 15 ARP packets in every one-second interval. If the burst

interval is 5 seconds, then the Switch accepts a maximum of 75 ARP packets in every five-

second interval.

Enter the length (1-15 seconds) of the burst interval.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel

to save your changes to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values in this screen to their last-saved values.

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26.8.2 ARP Inspection VLAN Configure

Use this screen to enable ARP inspection on each VLAN and to specify when the Switch generates log

messages for receiving ARP packets from each VLAN. To open this screen, click Advanced Application

> IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > Configure > VLAN.

Figure 188 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > Configure > VLAN

The following table describes the labels in this screen.

26.9 IPv6 Source Guard Overview

The purpose of IPv6 source guard is to distinguish between authorized and unauthorized users by using

a binding table that validates the source of IPv6 traffic. The binding table can be manually created or

be learned through Dynamic Host Configuration Protocol version 6 snooping (DHCPv6 snooping). IPv6

source guard can deny IPv6 traffic from an unknown source. The IPv6 source guard binding table

includes:

Table 116 IP Source Guard > IPv4 Source Guard Setup > ARP Inspection > Configure > VLAN

LABEL DESCRIPTION

VLAN Search by

VID

Specify the VLANs you want to manage in the section below. Use a comma (,) to separate

individual VLANs or a dash (-) to indicates a range of VLANs. For example, “3,4” or “3-9”.

Search Click this to display the specified range of VLANs in the section below.

VID This field displays the VLAN ID of each VLAN in the range specified above. If you configure the

* VLAN, the settings are applied to all VLANs.

Enabled Select Yes to enable ARP inspection on the VLAN. Select No to disable ARP inspection on the

VLAN.

Log Specify when the Switch generates log messages for receiving ARP packets from the VLAN.

None: The Switch does not generate any log messages when it receives an ARP packet from

the VLAN.

Deny: The Switch generates log messages when it discards an ARP packet from the VLAN.

Permit: The Switch generates log messages when it forwards an ARP packet from the VLAN.

All: The Switch generates log messages every time it receives an ARP packet from the VLAN.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values in this screen to their last-saved values.

Change Pages Click Previous Page or Next Page to show the previous/next screen if all status information

cannot be seen in one screen.

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• IPv6 address

• IPv6 prefix

• VLAN ID

• Port number

• MAC address

Enable IPv6 source guard on a port for the Switch to check incoming IPv6 packets on that port. A

packet is allowed when it matches any entry in the IPSG binding table. If a user tries to send IPv6 packets

to the Switch that do not match an entry in the IPSG binding table, the Switch will drop these packets.

The Switch forwards matching traffic normally. The IPv6 source guard related screens are available in

standalone mode.

26.10 IPv6 Source Binding Status

Use this screen to look at the current IPv6 dynamic and static bindings and to remove dynamic bindings

based on IPv6 address and/or IPv6 prefix. Bindings are used to distinguish between authorized and

unauthorized packets in the network. The Switch learns the bindings by snooping DHCP packets

(dynamic bindings) and from information provided manually by administrators (static bindings). To open

this screen, click Advanced Application > IP Source Guard > IPv6 Source Binding Status.

Figure 189 Advanced Application > IP Source Guard > IPv6 Source Binding Status

The following table describes the labels in this screen.

Table 117 Advanced Application > IP Source Guard > IPv6 Source Binding Status

LABEL DESCRIPTION

Clear Dynamic

Source Binding

Specify how you want the Switch to remove dynamic IPv6 source binding entries when you

click Flush.

• Select All to remove all of the dynamic entries from the IPv6 source binding table.

• Select IPv6 Address and enter an IPv6 address to remove the dynamic entries snooped

with the specified IPv6 address.

• Select IPv6 Prefix and enter a Prefix address to remove the dynamic entries snooped with

the specified Prefix address.

Flush Click this to remove dynamic IPv6 source binding entries according to your selections.

Cancel Click this to reset the values above based or if not applicable, to clear the fields above.

Index This field displays a sequential number for each binding.

Source Address This field displays the source IP address in the binding. If the entry is blank, this field will not be

checked in the binding.

MAC Address This field displays the source MAC address in the binding. If the entry is blank, this field will not

be checked in the binding.

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26.11 IPv6 Static Binding Setup

Use this screen to manually create an IPv6 source guard binding table entry and manage IPv6 static

bindings. Static bindings are uniquely identified by the source IPv6 address / prefix. Each source IPv6

address / prefix can only be in one static binding. If you try to create a static binding with the same

source IPv6 address / prefix as an existing static binding, the new static binding replaces the original

one. To open this screen, click Advanced Application > IP Source Guard > IPv6 Static Binding Setup.

Figure 190 Advanced Application > IP Source Guard > IPv6 Static Binding Setup

The following table describes the labels in this screen.

VLAN This field displays the source VLAN ID in the binding. If the entry is blank, this field will not be

checked in the binding.

Port This field displays the port number in the binding. If this field is blank, the binding applies to all

ports.

Lease This field displays how many days, hours, minutes, and seconds the binding is valid; for

example, 2d3h4m5s means the binding is still valid for 2 days, 3 hours, 4 minutes, and 5

seconds. This field displays infinity if the binding is always valid (for example, a static binding).

Type This field displays how the Switch learned the binding.

S: This static binding was learned from information provided manually by an administrator.

DH: This dhcp-snooping binding was learned by snooping DHCP packets.

Table 117 Advanced Application > IP Source Guard > IPv6 Source Binding Status

LABEL DESCRIPTION

Table 118 Advanced Application > IP Source Guard > IPv6 Static Binding Setup

LABEL DESCRIPTION

IPv6 Static Binding

Source Address Enter the IPv6 address or IPv6 prefix and prefix length in the binding.

MAC Address Enter the source MAC address in the binding. If this binding doesn’t check this field, select

Any.

Note: You cannot choose Any for all three of MAC Address, VLAN and Port. You

must fill in at least one.

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26.12 IPv6 Source Guard Policy Setup

Use this screen to have IPv6 source guard forward valid IPv6 addresses and/or IPv6 prefixes that are

stored in the binding table and allow or block data traffic from all link-local addresses. To open this

screen, click Advanced Application > IP Source Guard > IPv6 Source Guard Policy Setup.

•If you select Validate Address and not Validate Prefix, traffic for a binding entry that matches a IPv6

address and VLAN ID, port number, and MAC address will be forwarded. If this binding entry is a IPv6

prefix, the traffic will be denied.

•If you select Validate Prefix and not Validate Address, traffic for a binding entry that matches a IPv6

prefix and VLAN ID, port number, and MAC address will be forwarded. If this binding entry is a IPv6

address, the traffic will be denied.

•If you select both Validate Prefix and Validate Address then traffic matching either IPv6 address or

prefix will be forwarded.

Figure 191 Advanced Application > IP Source Guard > IPv6 Source Guard Policy Setup

VLAN Enter the source VLAN ID in the binding. If this binding doesn’t check this field, select Any.

Port Specify the port(s) in the binding. If this binding has one port, select the first radio button and

enter the port number in the field to the right.

Add Click this to create the specified static binding or to update an existing one.

Cancel Click this to reset the values above based or if not applicable, to clear the fields above.

Clear Click this to clear the fields above.

Index This field displays a sequential number for each binding.

Source Address This field displays the IPv6 address or IPv6 prefix and prefix length in the binding.

MAC Address This field displays the source MAC address in the binding. If the entry is blank, this field will not

be checked in the binding.

VLAN This field displays the source VLAN ID in the binding. If the entry is blank, this field will not be

checked in the binding.

Port This field displays the port number in the binding. If this field is blank, the binding applies to all

ports.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Select an entry check box and click Delete to remove the specified entry.

Cancel Click this to clear the Delete check boxes above.

Table 118 Advanced Application > IP Source Guard > IPv6 Static Binding Setup

LABEL DESCRIPTION

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The following table describes the labels in this screen.

26.13 IPv6 Source Guard Port Setup

Use this screen to apply configured IPv6 source guard policies to ports you specify. Use port * to apply a

policy to all ports. To open this screen, click Advanced Application > IP Source Guard > IPv6 Source

Guard Port Setup.

Figure 192 Advanced Application > IP Source Guard > IPv6 Source Guard Port Setup

Table 119 Advanced Application > IP Source Guard > IPv6 Source Guard Policy Setup

LABEL DESCRIPTION

Name Enter a descriptive name for identification purposes for this IPv6 source guard policy.

Validate Address Select Validate Address to have IPv6 source guard forward valid addresses that are stored in

the binding table.

Validate Prefix Select Validate Prefix to have IPv6 source guard forward valid prefixes that are stored in the

binding table.

Link Local Select Permit to allow data traffic from all link-local addresses; otherwise leave the setting at

Deny. A link-local address is an IPv6 unicast address that can be automatically configured on

any interface using the link-local prefix FE80::/10 and the interface identifier in the modified

EUI-64 format.

Add Click this to create the IPv6 source guard policy or to update an existing one.

Cancel Click this to reset the values above or if not applicable, to clear the fields above.

Clear Click this to clear the fields above.

Index This field displays a sequential number for each policy.

Name This field displays the descriptive name for identification purposes for this IPv6 source guard

policy.

Validate Address This field displays the Validate Address status for this IPv6 source guard policy.

Validate Prefix This field displays the Validate Prefix status for this IPv6 source guard policy.

Link Local This field displays the Link Local traffic status for this IPv6 source guard policy.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Select an entry checkbox and click Delete to remove the specified entry.

Cancel Click this to clear the Delete check boxes above.

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The following table describes the labels in this screen.

26.14 IPv6 Snooping Policy Setup

Use this screen to dynamically create an IPv6 source guard binding table using a DHCPv6 snooping

policy. A DHCPv6 snooping policy lets the Switch sniff DHCPv6 packets sent from a DHCPv6 server to a

DHCPv6 client when it is assigning an IPv6 address. When a DHCPv6 client successfully gets a valid IPv6

address, DHCPv6 snooping builds the binding table dynamically. To open this screen, click Advanced

Application > IP Source Guard > IPv6 Snooping Policy Setup.

Note: If you do not select Protocol and Prefix Glean, then the Switch cannot perform DHCPv6

snooping.

Figure 193 Advanced Application > IP Source Guard > IPv6 Snooping Policy Setup

The following table describes the labels in this screen.

Table 120 Advanced Application > IP Source Guard > IPv6 Source Guard Port Setup

LABEL DESCRIPTION

Port This field displays the port number.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Policy Name Select an IPv6 source guard policy that the Switch will apply to this port.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values in this screen to their last-saved values.

Table 121 Advanced Application > IP Source Guard > IPv6 Snooping Policy Setup

LABEL DESCRIPTION

Name Enter a descriptive name for identification purposes for this IPv6 snooping policy.

Protocol Select DHCP to let the Switch sniff DHCPv6 packets sent from a DHCPv6 server to a DHCPv6

client.

Prefix Glean Select this to learn the IPv6 prefix and length from DHCPv6 sniffed packets.

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26.15 IPv6 Snooping VLAN Setup

Use this screen to enable a DHCPv6 snooping policy on a specific VLAN interface. To open this screen,

click Advanced Application > IP Source Guard > IPv6 Snooping VLAN Setup.

Figure 194 Advanced Application > IP Source Guard > IPv6 Snooping VLAN Setup

The following table describes the labels in this screen.

Limit Address

Count

This is the number of IPv6 addresses and prefixes learned using the IPv6 snooping policy.

Note: The maximum limit address count is the maximum size of the IPv6 source

guard binding table. See the product datasheet for the latest specifications.

Add Click this to create the IPv6 source guard policy or to update an existing one.

Cancel Click this to reset the values above or if not applicable, to clear the fields above.

Clear Click this to clear the fields above.

Index This field displays a sequential number for each IPv6 snooping policy.

Name This field displays the descriptive name for identification purposes for this IPv6 source guard

policy.

Protocol This field displays the protocols learned from DHCPv6 sniffed packets.

Prefix Glean This field displays the IPv6 prefixes learned from DHCPv6 sniffed packets.

Limit Address

Count

This field displays the number of IPv6 addresses and prefixes learned using the IPv6 snooping

policy.

Delete Select an entry check box and click Delete to remove the specified entry.

Cancel Click this to clear the Delete check boxes above.

Table 121 Advanced Application > IP Source Guard > IPv6 Snooping Policy Setup

LABEL DESCRIPTION

Table 122 Advanced Application > IP Source Guard > IPv6 Snooping VLAN Setup

LABEL DESCRIPTION

Interface Select the VLAN interface to apply the selected DHCPv6 snooping policy.

Policy Select the IPv6 snooping policy to apply to this VLAN interface.

Add Click this to create the IPv6 source guard policy or to update an existing one.

Cancel Click this to reset the values above or if not applicable, to clear the fields above.

Clear Click this to clear the fields above.

Index This field displays a sequential number for each binding.

Interface This field displays the VLAN interface.

Policy This field displays the DHCPv6 snooping policy.

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26.16 IPv6 DHCP Trust Setup

Use this screen to specify which ports are trusted for DHCPv6 snooping. To open this screen, click

Advanced Application > IP Source Guard > IPv6 DHCP Trust Setup.

Note: DHCPv6 solicit packets are sent from a DHCPv6 client to a DHCPv6 server. Reply

packets from a DHCPv6 server connected to an untrusted port are discarded.

Use port * to have all ports be Untrusted or Trusted.

Figure 195 Advanced Application > IP Source Guard > IPv6 DHCP Trust Setup

The following table describes the labels in this screen.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Select an entry check box and click Delete to remove the specified entry.

Cancel Click this to clear the Delete check boxes above.

Table 122 Advanced Application > IP Source Guard > IPv6 Snooping VLAN Setup

LABEL DESCRIPTION

Table 123 Advanced Application > IP Source Guard > IPv6 DHCP Trust Setup

LABEL DESCRIPTION

Trust Setting

Active Select this to specify whether ports are trusted or untrusted ports for DHCP snooping. If you do

not select this then IPv6 DHCP Trust is not used and all ports are automatically trusted.

Port Setting

Port This field displays the port number.

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26.17 Technical Reference

This section provides technical background information on the topics discussed in this chapter.

26.17.1 DHCP Snooping Overview

Use DHCP snooping to filter unauthorized DHCP packets on the network and to build the binding table

dynamically. This can prevent clients from getting IP addresses from unauthorized DHCP servers.

26.17.1.1 Trusted vs. Untrusted Ports

Every port is either a trusted port or an untrusted port for DHCP snooping. This setting is independent of

the trusted/untrusted setting for ARP inspection. You can also specify the maximum number for DHCP

packets that each port (trusted or untrusted) can receive each second.

Trusted ports are connected to DHCP servers or other switches. The Switch discards DHCP packets from

trusted ports only if the rate at which DHCP packets arrive is too high. The Switch learns dynamic

bindings from trusted ports.

Note: The Switch will drop all DHCP requests if you enable DHCP snooping and there are no

trusted ports.

Untrusted ports are connected to subscribers. The Switch discards DHCP packets from untrusted ports in

the following situations:

• The packet is a DHCP server packet (for example, OFFER, ACK, or NACK).

• The source MAC address and source IP address in the packet do not match any of the current

bindings.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Trusted State Select whether this port is a trusted port (Trusted) or an untrusted port (Untrusted).

Trusted ports are connected to DHCPv6 servers or other switches.

Untrusted ports are connected to subscribers, and the Switch discards DHCPv6 packets from

untrusted ports in the following situations:

• The packet is a DHCPv6 server packet (for example, ADVERTISE, REPLY, or RELAY-REPLY).

• The source MAC address and source IP address in the packet do not match any of the

current bindings.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values in this screen to their last-saved values.

Table 123 Advanced Application > IP Source Guard > IPv6 DHCP Trust Setup

LABEL DESCRIPTION

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• The packet is a RELEASE or DECLINE packet, and the source MAC address and source port do not

match any of the current bindings.

• The rate at which DHCP packets arrive is too high.

26.17.1.2 DHCP Snooping Database

The Switch stores the binding table in volatile memory. If the Switch restarts, it loads static bindings from

permanent memory but loses the dynamic bindings, in which case the devices in the network have to

send DHCP requests again. As a result, it is recommended you configure the DHCP snooping database.

The DHCP snooping database maintains the dynamic bindings for DHCP snooping and ARP inspection

in a file on an external TFTP server. If you set up the DHCP snooping database, the Switch can reload the

dynamic bindings from the DHCP snooping database after the Switch restarts.

You can configure the name and location of the file on the external TFTP server. The file has the following

format:

Figure 196 DHCP Snooping Database File Format

The <initial-checksum> helps distinguish between the bindings in the latest update and the bindings

from previous updates. Each binding consists of 72 bytes, a space, and another checksum that is used

to validate the binding when it is read. If the calculated checksum is not equal to the checksum in the

file, that binding and all others after it are ignored.

26.17.1.3 DHCP Relay Option 82 Information

The Switch can add information to DHCP requests that it does not discard. This provides the DHCP server

more information about the source of the requests. The Switch can add the following information:

• Slot ID (1 byte), port ID (1 byte), and source VLAN ID (2 bytes)

• System name (up to 32 bytes)

This information is stored in an Agent Information field in the option 82 field of the DHCP headers of client

DHCP request frames. See Chapter 41 on page 343 for more information about DHCP relay option 82.

When the DHCP server responds, the Switch removes the information in the Agent Information field

before forwarding the response to the original source.

You can configure this setting for each source VLAN. This setting is independent of the DHCP relay

settings (Chapter 41 on page 343).

26.17.1.4 Configuring DHCP Snooping

Follow these steps to configure DHCP snooping on the Switch.

<initial-checksum>

TYPE DHCP-SNOOPING

VERSION 1

BEGIN

<binding-1> <checksum-1>

<binding-2> <checksum-1-2>

...

<binding-n> <checksum-1-2-..-n>

END

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1Enable DHCP snooping on the Switch.

2Enable DHCP snooping on each VLAN, and configure DHCP relay option 82.

3Configure trusted and untrusted ports, and specify the maximum number of DHCP packets that each

port can receive per second.

4Configure static bindings.

26.17.2 ARP Inspection Overview

Use ARP inspection to filter unauthorized ARP packets on the network. This can prevent many kinds of

man-in-the-middle attacks, such as the one in the following example.

Figure 197 Example: Man-in-the-middle Attack

In this example, computer B tries to establish a connection with computer A. Computer X is in the same

broadcast domain as computer A and intercepts the ARP request for computer A. Then, computer X

does the following things:

• It pretends to be computer A and responds to computer B.

• It pretends to be computer B and sends a message to computer A.

As a result, all the communication between computer A and computer B passes through computer X.

Computer X can read and alter the information passed between them.

26.17.2.1 ARP Inspection and MAC Address Filters

When the Switch identifies an unauthorized ARP packet, it automatically creates a MAC address filter to

block traffic from the source MAC address and source VLAN ID of the unauthorized ARP packet. You

can configure how long the MAC address filter remains in the Switch.

These MAC address filters are different than regular MAC address filters (Chapter 12 on page 136).

• They are stored only in volatile memory.

• They do not use the same space in memory that regular MAC address filters use.

• They appear only in the ARP Inspection screens and commands, not in the MAC Address Filter screens

and commands.

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26.17.2.2 Trusted vs. Untrusted Ports

Every port is either a trusted port or an untrusted port for ARP inspection. This setting is independent of

the trusted/untrusted setting for DHCP snooping. You can also specify the maximum rate at which the

Switch receives ARP packets on untrusted ports.

The Switch does not discard ARP packets on trusted ports for any reason.

The Switch discards ARP packets on untrusted ports in the following situations:

• The sender’s information in the ARP packet does not match any of the current bindings.

• The rate at which ARP packets arrive is too high.

26.17.2.3 Syslog

The Switch can send syslog messages to the specified syslog server (Chapter 47 on page 395) when it

forwards or discards ARP packets. The Switch can consolidate log messages and send log messages in

batches to make this mechanism more efficient.

26.17.2.4 Configuring ARP Inspection

Follow these steps to configure ARP inspection on the Switch.

1Configure DHCP snooping. See Section 26.17.1.4 on page 264.

Note: It is recommended you enable DHCP snooping at least one day before you enable

ARP inspection so that the Switch has enough time to build the binding table.

2Enable ARP inspection on each VLAN.

3Configure trusted and untrusted ports, and specify the maximum number of ARP packets that each port

can receive per second.

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CHAPTER 27

Loop Guard

27.1 Loop Guard Overview

This chapter shows you how to configure the Switch to guard against loops on the edge of your network.

Loop guard allows you to configure the Switch to shut down a port if it detects that packets sent out on

that port loop back to the Switch. While you can use Spanning Tree Protocol (STP) to prevent loops in the

core of your network. STP cannot prevent loops that occur on the edge of your network.

Figure 198 Loop Guard vs. STP

Refer to Section 27.1.2 on page 267 for more information.

27.1.1 What You Can Do

Use the Loop Guard screen (Section 27.2 on page 269) to enable loop guard on the Switch and in

specific ports.

27.1.2 What You Need to Know

Loop guard is designed to handle loop problems on the edge of your network. This can occur when a

port is connected to a Switch that is in a loop state. Loop state occurs as a result of human error. It

happens when two ports on a switch are connected with the same cable. When a switch in loop state

sends out broadcast messages the messages loop back to the switch and are re-broadcast again and

again causing a broadcast storm.

If a switch (not in loop state) connects to a switch in loop state, then it will be affected by the switch in

loop state in the following way:

• It will receive broadcast messages sent out from the switch in loop state.

• It will receive its own broadcast messages that it sends out as they loop back. It will then re-broadcast

those messages again.

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The following figure shows port N on switch A connected to switch B. Switch B is in loop state. When

broadcast or multicast packets leave port N and reach switch B, they are sent back to port N on A as

they are rebroadcast from B.

Figure 199 Switch in Loop State

The loop guard feature checks to see if a loop guard enabled port is connected to a switch in loop

state. This is accomplished by periodically sending a probe packet and seeing if the packet returns on

the same port. If this is the case, the Switch will shut down the port connected to the switch in loop state.

The following figure shows a loop guard enabled port N on switch A sending a probe packet P to switch

B. Since switch B is in loop state, the probe packet P returns to port N on A. The Switch then shuts down

port N to ensure that the rest of the network is not affected by the switch in loop state.

Figure 200 Loop Guard - Probe Packet

The Switch also shuts down port N if the probe packet returns to switch A on any other port. In other

words loop guard also protects against standard network loops. The following figure illustrates three

switches forming a loop. A sample path of the loop guard probe packet is also shown. In this example,

the probe packet is sent from port N and returns on another port. As long as loop guard is enabled on

port N. The Switch will shut down port N if it detects that the probe packet has returned to the Switch.

Figure 201 Loop Guard - Network Loop

Note: After resolving the loop problem on your network you can re-activate the disabled port

via the web configurator (see Section 8.7 on page 88).

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27.2 Loop Guard Setup

Click Advanced Application > Loop Guard in the navigation panel to display the screen as shown.

Note: The loop guard feature can not be enabled on the ports that have Spanning Tree

Protocol (RSTP, MRSTP or MSTP) enabled.

Figure 202 Advanced Application > Loop Guard

The following table describes the labels in this screen.

Table 124 Advanced Application > Loop Guard

LABEL DESCRIPTION

Active Select this option to enable loop guard on the Switch.

The Switch generates syslog, internal log messages as well as SNMP traps when it shuts down a

port via the loop guard feature.

Port This field displays the port number. * means all ports.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select this check box to enable the loop guard feature on this port. The Switch sends probe

packets from this port to check if the switch it is connected to is in loop state. If the switch that

this port is connected is in loop state the Switch will shut down this port.

Clear this check box to disable the loop guard feature.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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CHAPTER 28

VLAN Mapping

This chapter shows you how to configure VLAN mapping on the Switch.

28.1 VLAN Mapping Overview

With VLAN mapping enabled, the Switch can map the VLAN ID and priority level of packets received

from a private network to those used in the service provider’s network.

The Switch checks incoming traffic from the switch ports (non-management ports) against the VLAN

mapping table first, the MAC learning table and then the VLAN table before forwarding them through

the Gigabit uplink port. If the incoming packets are untagged or tagged but do not match an entry in

the VLAN mapping table, the Switch doesn’t translate the existing VLAN ID and uses the MAC table

and/or VLAN table to decide how to forward the packets.

28.1.1 VLAN Mapping Example

In the following example figure, packets that carry VLAN ID 12 and are received on port 3 match a pre-

configured VLAN mapping rule. The Switch translates the VLAN ID from 12 into 123 before forwarding the

packets.

Figure 203 VLAN mapping example

28.1.2 What You Can Do

• Use the VLAN Mapping screen (Section 28.2 on page 271) to enable VLAN mapping on the Switch and

ports.

• Use the VLAN Mapping Configure screen (Section 28.2.1 on page 271) to enable and edit the VLAN

mapping rules.

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28.2 Enable VLAN Mapping

Click Advanced Application and then VLAN Mapping in the navigation panel to display the screen as

shown.

Figure 204 Advanced Application > VLAN Mapping

The following table describes the labels in this screen.

28.2.1 VLAN Mapping Configure

Click the VLAN Mapping Configure link in the VLAN Mapping screen to display the screen as shown. Use

this screen to enable and edit the VLAN mapping rule(s).

Table 125 Advanced Application > VLAN Mapping

LABEL DESCRIPTION

Active Select this option to enable VLAN mapping on the Switch.

Port This field displays the port number.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select this check box to enable the VLAN mapping feature on this port. Clear this check box to

disable the VLAN mapping feature.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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Figure 205 Advanced Application > VLAN Mapping > VLAN Mapping Configuration

The following table describes the labels in this screen.

Table 126 Advanced Application > VLAN Mapping > VLAN Mapping Configuration

LABEL DESCRIPTION

Active Check this box to activate this rule.

Name Enter a descriptive name (up to 32 printable ASCII characters) for identification purposes.

Port Type a port to be included in this rule.

VID Enter a VLAN ID from 1 to 4094. This is the VLAN tag carried in the packets and will be translated

into the VID you specified in the Translated VID field.

Translated VID Enter a VLAN ID (from 1 to 4094) into which the customer VID carried in the packets will be

translated.

Priority Select a priority level (from 0 to 7). This is the priority level that replaces the customer priority

level in the tagged packets or adds to the untagged packets.

Add Click this to create a new entry or to update an existing one.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your

changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to your previous configuration.

Index This is the number of the VLAN mapping entry in the table. Click on an index number to change

the settings.

Active This shows whether this entry is activated or not.

Name This is the descriptive name for this rule.

Port This is the port number to which this rule is applied. I

VID This is the customer VLAN ID in the incoming packets.

Translated VID This is the VLAN ID that replaces the customer VLAN ID in the tagged packets.

Priority This is the priority level that replaces the customer priority level in the tagged packets.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Check the rule(s) that you want to remove in the Delete column and then click the Delete

button.

Cancel Click Cancel to clear the Delete check boxes.

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CHAPTER 29

Layer 2 Protocol Tunneling

29.1 Layer 2 Protocol Tunneling Overview

This chapter shows you how to configure layer 2 protocol tunneling on the Switch.

29.1.1 What You Can Do

Use the Layer 2 Protocol Tunnel screen (Section 29.2 on page 274) to enable layer 2 protocol tunneling

on the Switch and specify a MAC address with which the Switch uses to encapsulate the layer 2

protocol packets by replacing the destination MAC address in the packets.

29.1.2 What You Need to Know

Layer 2 protocol tunneling (L2PT) is used on the service provider's edge devices.

L2PT allows edge switches (1 and 2 in the following figure) to tunnel layer 2 STP (Spanning Tree Protocol),

CDP (Cisco Discovery Protocol) and VTP (VLAN Trunking Protocol) packets between customer switches

(A, B and C in the following figure) connected through the service provider’s network. The edge switch

encapsulates layer 2 protocol packets with a specific MAC address before sending them across the

service provider’s network to other edge switches.

Figure 206 Layer 2 Protocol Tunneling Network Scenario

In the following example, if you enable L2PT for STP, you can have switches A, B, C and D in the same

spanning tree, even though switch A is not directly connected to switches B, C and D. Topology change

information can be propagated throughout the service provider’s network.

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To emulate a point-to-point topology between two customer switches at different sites, such as A and B,

you can enable protocol tunneling on edge switches 1 and 2 for PAgP (Port Aggregation Protocol),

LACP or UDLD (UniDirectional Link Detection).

Figure 207 L2PT Network Example

29.1.2.1 Layer 2 Protocol Tunneling Mode

Each port can have two layer 2 protocol tunneling modes, Access and Tunnel.

• The Access port is an ingress port on the service provider's edge device (1 or 2 in Figure 207 on page

274) and connected to a customer switch (A or B). Incoming layer 2 protocol packets received on an

access port are encapsulated and forwarded to the tunnel ports.

• The Tunnel port is an egress port at the edge of the service provider's network and connected to

another service provider’s switch. Incoming encapsulated layer 2 protocol packets received on a

tunnel port are decapsulated and sent to an access port.

29.2 Configuring Layer 2 Protocol Tunneling

Click Advanced Application > Layer 2 Protocol Tunneling in the navigation panel to display the screen

as shown.

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Figure 208 Advanced Application > Layer 2 Protocol Tunneling

The following table describes the labels in this screen.

Table 127 Advanced Application > Layer 2 Protocol Tunneling

LABEL DESCRIPTION

Active Select this to enable layer 2 protocol tunneling on the Switch.

Destination

MAC Address

Specify a MAC address with which the Switch uses to encapsulate the layer 2 protocol packets

by replacing the destination MAC address in the packets.

Note: The MAC address can be either a unicast MAC address or multicast MAC

address. If you use a unicast MAC address, make sure the MAC address does

not exist in the address table of a switch on the service provider’s network.

Note: All the edge switches in the service provider’s network should be set to use the

same MAC address for encapsulation.

Port This field displays the port number. * means all ports.

* Use this row to make the setting the same for all ports. Use this row first and then make

adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

CDP Select this option to have the Switch tunnel CDP (Cisco Discovery Protocol) packets so that

other Cisco devices can be discovered through the service provider’s network.

STP Select this option to have the Switch tunnel STP (Spanning Tree Protocol) packets so that STP can

run properly across the service provider’s network and spanning trees can be set up based on

bridge information from all (local and remote) networks.

VTP Select this option to have the Switch tunnel VTP (VLAN Trunking Protocol) packets so that all

customer switches can use consistent VLAN configuration through the service provider’s

network.

Point to Point The Switch supports PAgP (Port Aggregation Protocol), LACP (Link Aggregation Control

Protocol) and UDLD (UniDirectional Link Detection) tunneling for a point-to-point topology.

Both PAgP and UDLD are Cisco’s proprietary data link layer protocols. PAgP is similar to LACP

and used to set up a logical aggregation of Ethernet ports automatically. UDLD is to determine

the link’s physical status and detect a unidirectional link.

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PAGP Select this option to have the Switch send PAgP packets to a peer to automatically negotiate

and build a logical port aggregation.

LACP Select this option to have the Switch send LACP packets to a peer to dynamically creates and

manages trunk groups.

UDLD Select this option to have the Switch send UDLD packets to a peer’s port it connected to

monitor the physical status of a link.

Mode Select Access to have the Switch encapsulate the incoming layer 2 protocol packets and

forward them to the tunnel port(s). Select Access for ingress ports at the edge of the service

provider's network.

Note: You can enable L2PT services for STP, LACP, VTP, CDP, UDLD, and PAGP on the

access port(s) only.

Select Tunnel for egress ports at the edge of the service provider's network. The Switch

decapsulates the encapsulated layer 2 protocol packets received on a tunnel port by

changing the destination MAC address to the original one, and then forward them to an access

port. If the service(s) is not enabled on an access port, the protocol packets are dropped.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 127 Advanced Application > Layer 2 Protocol Tunneling (continued)

LABEL DESCRIPTION

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CHAPTER 30

PPPoE

30.1 PPPoE Intermediate Agent Overview

This chapter describes how the Switch gives a PPPoE termination server additional information that the

server can use to identify and authenticate a PPPoE client.

A PPPoE Intermediate Agent (PPPoE IA) is deployed between a PPPoE server and PPPoE clients. It helps

the PPPoE server identify and authenticate clients by adding subscriber line specific information to

PPPoE discovery packets from clients on a per-port or per-port-per-VLAN basis before forwarding them

to the PPPoE server.

30.1.1 What You Can Do

• Use the PPPoE screen (Section 30.2 on page 279) to display the main PPPoE screen.

• Use the Intermediate Agent screen (Section 30.3 on page 280) to enable the PPPoE Intermediate

Agent on the Switch.

• Use the PPPoE IA Per-Port screen (Section 30.3.1 on page 281) to set the port state and configure

PPPoE intermediate agent sub-options on a per-port basis.

• Use the PPPoE IA Per-Port Per-VLAN screen (Section 30.3.2 on page 282) to configure PPPoE IA settings

that apply to a specific VLAN on a port.

• Use the PPPoE IA for VLAN (Section 30.3.3 on page 283) to enable the PPPoE Intermediate Agent on a

VLAN.

30.1.2 What You Need to Know

Read on for concepts on ARP that can help you configure the screen in this chapter.

30.1.2.1 PPPoE Intermediate Agent Tag Format

If the PPPoE Intermediate Agent is enabled, the Switch adds a vendor-specific tag to PADI (PPPoE

Active Discovery Initialization) and PADR (PPPoE Active Discovery Request) packets from PPPoE clients.

This tag is defined in RFC 2516 and has the following format for this feature.

Table 128 PPPoE Intermediate Agent Vendor-specific Tag Format

Tag_Type

(0x0105)

Tag_Len Value i1 i2

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The Tag_Type is 0x0105 for vendor-specific tags, as defined in RFC 2516. The Tag_Len indicates the

length of Value, i1 and i2. The Value is the 32-bit number 0x00000DE9, which stands for the “ADSL Forum”

IANA entry. i1 and i2 are PPPoE intermediate agent sub-options, which contain additional information

about the PPPoE client.

30.1.2.2 Sub-Option Format

There are two types of sub-option: “Agent Circuit ID Sub-option” and “Agent Remote ID Sub-option”.

They have the following formats.

The 1 in the first field identifies this as an Agent Circuit ID sub-option and 2 identifies this as an Agent

Remote ID sub-option. The next field specifies the length of the field. The Switch takes the Circuit ID string

you manually configure for a VLAN on a port as the highest priority and the Circuit ID string for a port as

the second priority. In addition, the Switch puts the PPPoE client’s MAC address into the Agent Remote

ID Sub-option if you do not specify any user-defined string.

Flexible Circuit ID Syntax with Identifier String and Variables

If you do not configure a Circuit ID string for a VLAN on a specific port or for a specific port, the Switch

adds the user-defined identifier string and variables into the Agent Circuit ID Sub-option. The variables

can be the slot ID of the PPPoE client, the port number of the PPPoE client and/or the VLAN ID on the

PPPoE packet.

The identifier-string, slot ID, port number and VLAN ID are separated from each other by a pound key

(#), semi-colon (;), period (.), comma (,), forward slash (/) or space. An Agent Circuit ID Sub-option

example is “Switch/07/0123” and indicates the PPPoE packets come from a PPPoE client which is

connected to the Switch’s port 7 and belong to VLAN 123.

WT-101 Default Circuit ID Syntax

If you do not configure a Circuit ID string for a specific VLAN on a port or for a specific port, and disable

the flexible Circuit ID syntax in the PPPoE > Intermediate Agent screen, the Switch automatically

generates a Circuit ID string according to the default Circuit ID syntax which is defined in the DSL Forum

Table 129 PPPoE IA Circuit ID Sub-option Format: User-defined String

SubOpt Length Value

0x01

(1 byte)

String

(63 bytes)

Table 130 PPPoE IA Remote ID Sub-option Format

SubOpt Length Value

0x02

(1 byte)

MAC Address or String

(63 bytes)

Table 131 PPPoE IA Circuit ID Sub-option Format: Using Identifier String and Variables

SubOpt Length Value

0x01

(1 byte)

Identifier

String

(53 byte)

delimiter

(1 byte)

Slot ID

(1 byte)

delimiter

(1 byte)

Port No

(2 byte)

delimiter

(1 byte)

VLAN ID

bytes)

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Working Text (WT)-101. The default access node identifier is the host name of the PPPoE intermediate

agent and the eth indicates “Ethernet”.

30.1.2.3 Port State

Every port is either a trusted port or an untrusted port for the PPPoE intermediate agent. This setting is

independent of the trusted/untrusted setting for DHCP snooping or ARP inspection. You can also specify

the agent sub-options (circuit ID and remote ID) that the Switch adds to PADI and PADR packets from

PPPoE clients.

Trusted ports are connected to PPPoE servers.

• If a PADO (PPPoE Active Discovery Offer), PADS (PPPoE Active Discovery Session-confirmation), or

PADT (PPPoE Active Discovery Terminate) packet is sent from a PPPoE server and received on a

trusted port, the Switch forwards it to all other ports.

• If a PADI or PADR packet is sent from a PPPoE client but received on a trusted port, the Switch

forwards it to other trusted port(s).

Note: The Switch will drop all PPPoE discovery packets if you enable the PPPoE intermediate

agent and there are no trusted ports.

Untrusted ports are connected to subscribers.

• If a PADI, PADR, or PADT packet is sent from a PPPoE client and received on an untrusted port, the

Switch adds a vendor-specific tag to the packet and then forwards it to the trusted port(s).

• The Switch discards PADO and PADS packets which are sent from a PPPoE server but received on an

untrusted port.

30.2 PPPoE Screen

Use this screen to configure the PPPoE Intermediate Agent on the Switch.

Click Advanced Appl ication > PPPoE in the navigation panel to display the screen as shown. Click Click

Here to go to the Intermediate Agent screen.

Figure 209 Advanced Application > PPPoE Intermediate Agent

Table 132 PPPoE IA Circuit ID Sub-option Format: Defined in WT-101

SubOpt Length Value

0x01

(1 byte)

Access

Node

Identifier

(20 byte)

Space

byte)

eth

byte)

Space

byte)

Slot ID

byte)

Port No

(2 byte)

byte)

VLAN ID

bytes)

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30.3 PPPoE Intermediate Agent

Use this screen to configure the Switch to give a PPPoE termination server additional subscriber

information that the server can use to identify and authenticate a PPPoE client.

Click Advanced Application > PPPoE > Intermediate Agent in the navigation panel to display the screen

as shown.

Figure 210 Advanced Application > PPPoE > Intermediate Agent

The following table describes the labels in this screen.

Table 133 Advanced Application > PPPoE > Intermediate Agent

LABEL DESCRIPTION

Active Select this option to enable the PPPoE intermediate agent globally on the Switch.

access-node-

identifier

Enter up to 20 ASCII characters to identify the PPPoE intermediate agent. Hyphens (-) and

spaces are also allowed. The default is the Switch’s host name.

circuit-id Use this section to configure the Circuit ID field in the PADI and PADR packets.

The Circuit ID you configure for a specific port or for a specific VLAN on a port has priority over

this.

The Circuit ID you configure for a specific port (in the Advanced Application > PPPoE >

Intermediate Agent > Port screen) or for a specific VLAN on a port (in the Advanced Application

> PPPoE > Intermediate Agent > Port > VLAN screen) has priority over this. That means, if you also

want to configure PPPoE IA Per-Port or Per-Port Per-VLAN setting, leave the fields here empty

and configure circuit-id and remote-id in the Per-Port or Per-Port Per-VLAN screen.

Active Select this option to have the Switch add the user-defined identifier string and variables

(specified in the option field) to PADI or PADR packets from PPPoE clients.

If you leave this option unselected and do not configure any Circuit ID string on the Switch, the

Switch will use the string specified in the access-node-identifier field.

identifier-

string Specify a string that the Switch adds in the Agent Circuit ID sub-option. You can enter up to 53

ASCII characters. Spaces are allowed.

option Select the variables that you want the Switch to generate and add in the Agent Circuit ID sub-

option. The variable options include sp, sv, pv and spv which indicate combinations of slot-port,

slot-VLAN, port-VLAN and slot-port-VLAN respectively. The Switch enters a zero into the PADI and

PADR packets for the slot value.

delimiter Select a delimiter to separate the identifier-string, slot ID, port number and/or VLAN ID from each

other. You can use a pound key (#), semi-colon (;), period (.), comma (,), forward slash (/) or

space.

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30.3.1 PPPoE IA Per-Port

Use this screen to specify whether individual ports are trusted or untrusted ports and have the Switch

add extra information to PPPoE discovery packets from PPPoE clients on a per-port basis.

Note: The Switch will drop all PPPoE packets if you enable the PPPoE Intermediate Agent on

the Switch and there are no trusted ports.

Click the Port link in the Intermediate Agent screen to display the screen as shown.

Figure 211 Advanced Application > PPPoE > Intermediate Agent > Port

The following table describes the labels in this screen.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 133 Advanced Application > PPPoE > Intermediate Agent (continued)

LABEL DESCRIPTION

Table 134 Advanced Application > PPPoE > Intermediate Agent > Port

LABEL DESCRIPTION

Port This field displays the port number. * means all ports.

* Use this row to make the setting the same for all ports. Use this row first and then make

adjustments on a port-by-port basis.

Changes in this row are copied to all the ports as soon as you make them.

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30.3.2 PPPoE IA Per-Port Per-VLAN

Use this screen to configure PPPoE IA settings that apply to a specific VLAN on a port.

Click the VLAN link in the Intermediate Agent > Port screen to display the screen as shown.

Figure 212 Advanced Application > PPPoE > Intermediate Agent > Port > VLAN

Server Trusted

State

Select whether this port is a trusted port (Trusted) or an untrusted port (Untrusted).

Trusted ports are uplink ports connected to PPPoE servers.

If a PADO (PPPoE Active Discovery Offer), PADS (PPPoE Active Discovery Session-confirmation),

or PADT (PPPoE Active Discovery Terminate) packet is sent from a PPPoE server and received on

a trusted port, the Switch forwards it to all other ports.

If a PADI or PADR packet is sent from a PPPoE client but received on a trusted port, the Switch

forwards it to other trusted port(s).

Untrusted ports are downlink ports connected to subscribers.

If a PADI, PADR, or PADT packet is sent from a PPPoE client and received on an untrusted port,

the Switch adds a vendor-specific tag to the packet and then forwards it to the trusted port(s).

The Switch discards PADO and PADS packets which are sent from a PPPoE server but received

on an untrusted port.

Circuit-id Enter a string of up to 63 ASCII characters that the Switch adds into the Agent Circuit ID sub-

option for PPPoE discovery packets received on this port. Spaces are allowed.

The Circuit ID you configure for a specific VLAN on a port (in the Advanced Application > PPPoE

> Intermediate Agent > Port > VLAN screen) has the highest priority.

Remote-id Enter a string of up to 63 ASCII characters that the Switch adds into the Agent Remote ID sub-

option for PPPoE discovery packets received on this port. Spaces are allowed.

If you do not specify a string here or in the Remote-id field for a VLAN on a port, the Switch

automatically uses the PPPoE client’s MAC address.

The Remote ID you configure for a specific VLAN on a port (in the Advanced Application >

PPPoE > Intermediate Agent > Port > VLAN screen) has the highest priority.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 134 Advanced Application > PPPoE > Intermediate Agent > Port (continued)

LABEL DESCRIPTION

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The following table describes the labels in this screen.

30.3.3 PPPoE IA for VLAN

Use this screen to set whether the PPPoE Intermediate Agent is enabled on a VLAN and whether the

Switch appends the Circuit ID and/or Remote ID to PPPoE discovery packets from a specific VLAN.

Click the VLAN link in the Intermediate Agent screen to display the screen as shown.

Figure 213 Advanced Application > PPPoE > Intermediate Agent > VLAN

Table 135 Advanced Application > PPPoE > Intermediate Agent > Port > VLAN

LABEL DESCRIPTION

Show Port Enter a port number to show the PPPoE Intermediate Agent settings for the specified VLAN(s) on

the port.

Show VLAN Use this section to specify the VLANs you want to configure in the section below.

Start VID Enter the lowest VLAN ID you want to configure in the section below.

End VID Enter the highest VLAN ID you want to configure in the section below.

Apply Click Apply to display the specified range of VLANs in the section below.

Port This field displays the port number specified above.

VID This field displays the VLAN ID of each VLAN in the range specified above. If you configure the *

VLAN, the settings are applied to all VLANs.

* Use this row to make the setting the same for all VLANs. Use this row first and then make

adjustments on a VLAN-by-VLAN basis.

Changes in this row are copied to all the VLANs as soon as you make them.

Circuit-id Enter a string of up to 63 ASCII characters that the Switch adds into the Agent Circuit ID sub-

option for this VLAN on the specified port. Spaces are allowed.

The Circuit ID you configure here has the highest priority.

Remote-id Enter a string of up to 63 ASCII characters that the Switch adds into the Agent Remote ID sub-

option for this VLAN on the specified port. Spaces are allowed.

If you do not specify a string here or in the Remote-id field for a specific port, the Switch

automatically uses the PPPoE client’s MAC address.

The Remote ID you configure here has the highest priority.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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The following table describes the labels in this screen.

Table 136 Advanced Application > PPPoE > Intermediate Agent > VLAN

LABEL DESCRIPTION

Show VLAN Use this section to specify the VLANs you want to configure in the section below.

Start VID Enter the lowest VLAN ID you want to configure in the section below.

End VID Enter the highest VLAN ID you want to configure in the section below.

Apply Click Apply to display the specified range of VLANs in the section below.

VID This field displays the VLAN ID of each VLAN in the range specified above. If you configure the *

VLAN, the settings are applied to all VLANs.

* Use this row to make the setting the same for all VLANs. Use this row first and then make

adjustments on a VLAN-by-VLAN basis.

Changes in this row are copied to all the VLANs as soon as you make them.

Enabled Select this option to turn on the PPPoE Intermediate Agent on a VLAN.

Circuit-id Select this option to make the Circuit ID settings for a specific VLAN take effect.

Remote-id Select this option to make the Remote ID settings for a specific VLAN take effect.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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CHAPTER 31

Error Disable

31.1 Error Disable Overview

This chapter shows you how to configure the rate limit for control packets on a port, and set the Switch

to take an action (such as to shut down a port or stop sending packets) on a port when the Switch

detects a pre-configured error. It also shows you how to configure the Switch to automatically undo the

action after the error is gone.

31.1.1 CPU Protection Overview

Switches exchange protocol control packets in a network to get the latest networking information. If a

switch receives large numbers of control packets, such as ARP, BPDU or IGMP packets, which are to be

processed by the CPU, the CPU may become overloaded and be unable to handle regular tasks

properly.

The CPU protection feature allows you to limit the rate of ARP, BPDU and IGMP packets to be delivered

to the CPU on a port. This enhances the CPU efficiency and protects against potential DoS attacks or

errors from other network(s). You then can choose to drop control packets that exceed the specified

rate limit or disable a port on which the packets are received.

31.1.2 Error-Disable Recovery Overview

Some features, such as loop guard or CPU protection, allow the Switch to shut down a port or discard

specific packets on a port when an error is detected on the port. For example, if the Switch detects that

packets sent out the port(s) loop back to the Switch, the Switch can shut down the port(s)

automatically. After that, you need to enable the port(s) or allow the packets on a port manually via the

web configurator. With error-disable recovery, you can set the disabled port(s) to become active or

start receiving the packets again after the time interval you specify.

31.1.3 What You Can Do

• Use the Errdisable Status screen (Section 31.3 on page 286) to view whether the Switch detected that

control packets exceeded the rate limit configured for a port or a port is disabled according to the

feature requirements and what action you configure, and related information.

• Use the CPU Protection screen (Section 31.4 on page 288) to limit the maximum number of control

packets (ARP, BPDU and/or IGMP) that the Switch can receive or transmit on a port.

• Use the Errdisable Detect screen (Section 31.5 on page 289) to have the Switch detect whether the

control packets exceed the rate limit configured for a port and configure the action to take once the

limit is exceeded.

• Use the Errdisable Recovery screen (Section 31.6 on page 290) to set the Switch to automatically

undo an action after the error is gone.

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31.2 Error Disable Screen

Use this screen to go to the screens where you can configure error disable related settings. Click

Advanced Application > Errdisable in the navigation panel to open the following screen.

Figure 214 Advanced Application > Errdisable

The following table describes the labels in this screen.

31.3 Error-Disable Status

Use this screen to view whether the Switch detected that control packets exceeded the rate limit

configured for a port or a port is disabled according to the feature requirements and what action you

configure, and related information. Click the Click here link next to Errdisable Status in the Advanced

Application > Errdisable screen to display the screen as shown.

Table 137 Advanced Application > Errdisable

LABEL DESCRIPTION

Errdisable Status Click this link to view whether the Switch detected that control packets exceeded the rate

limit configured for a port or a port is disabled according to the feature requirements and

what action you configure, and related information.

CPU protection Click this link to limit the maximum number of control packets (ARP, BPDU and/or IGMP)

that the Switch can receive or transmit on a port.

Errdisable Detect Click this link to have the Switch detect whether the control packets exceed the rate limit

configured for a port and configure the action to take once the limit is exceeded.

Errdisable Recovery Click this link to set the Switch to automatically undo an action after the error is gone.

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Figure 215 Advanced Application > Errdisable > Errdisable Status

The following table describes the labels in this screen.

Table 138 Advanced Application > Errdisable > Errdisable Status

LABEL DESCRIPTION

Inactive-reason mode reset

Port List Enter the number of the port(s) (separated by a comma) on which you want to reset inactive-

reason status.

Cause Select the cause of inactive-reason mode you want to reset here.

Reset Press to reset the specified port(s) to handle ARP, BPDU or IGMP packets instead of ignoring

them, if the port(s) is in inactive-reason mode.

Errdisable Status

Port This is the number of the port on which you want to configure Errdisable Status.

Cause This displays the type of the control packet received on the port or the feature enabled on the

port and causing the Switch to take the specified action.

Active This field displays whether the control packets (ARP, BPDU, and/or IGMP) on the port is being

detected or not. It also shows whether loop guard is enabled on the port.

Mode This field shows the action that the Switch takes for the cause.

•inactive-port - The Switch disables the port.

•inactive-reason - The Switch drops all the specified control packets (such as BPDU) on the

port.

•rate-limitation - The Switch drops the additional control packets the port(s) has to handle in

every one second.

Rate This field displays how many control packets this port can receive or transmit per second. It can

be adjusted in CPU Protection. 0 means no rate limit.

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31.4 CPU Protection Configuration

Use this screen to limit the maximum number of control packets (ARP, BPDU and/or IGMP) that the

Switch can receive or transmit on a port. Click the Click Here link next to CPU protection in the

Advanced Application > Errdisable screen to display the screen as shown.

Note: After you configure this screen, make sure you also enable error detection for the

specific control packets in the Advanced Application > Errdisable > Errdisable Dete ct

screen.

Figure 216 Advanced Application > Errdisable > CPU protection

The following table describes the labels in this screen.

Status This field displays the errdisable status

•Forwarding: The Switch is forwarding packets. Rate-limitation mode is always in Forwarding

status.

•Err-disable: The Switch disables the port on which the control packets are received

(inactive-port) or drops specified control packets on the port (inactive-reason)

Recovery

Time Left

(secs)

This field displays the time (seconds) left before the port(s) becomes active of Errdisable

Recovery.

Total

Dropped This field displays the total packet number dropped by this port where the packet rate exceeds

the rate of mode rate-limitation.

Table 138 Advanced Application > Errdisable > Errdisable Status (continued)

LABEL DESCRIPTION

Table 139 Advanced Application > Errdisable > CPU protection

LABEL DESCRIPTION

Reason Select the type of control packet you want to configure here.

Port This field displays the port number. * means all ports.

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31.5 Error-Disable Detect Configuration

Use this screen to have the Switch detect whether the control packets exceed the rate limit configured

for a port and configure the action to take once the limit is exceeded. Click the Click Here link next to

Errdisable Detect link in the Advanced Application > Errdisable screen to display the screen as shown.

Figure 217 Advanced Application > Errdisable > Errdisable Detect

The following table describes the labels in this screen.

* Use this row to make the setting the same for all ports. Use this row first and then make

adjustments to each port if necessary.

Changes in this row are copied to all the ports as soon as you make them.

Rate Limit (pkt/s) Enter a number from 0 to 256 to specify how many control packets this port can receive or

transmit per second.

0 means no rate limit.

You can configure the action that the Switch takes when the limit is exceeded. See Section 31.5

on page 289 for detailed information.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 139 Advanced Application > Errdisable > CPU protection

LABEL DESCRIPTION

Table 140 Advanced Application > Errdisable > Errdisable Detect

LABEL DESCRIPTION

Cause This field displays the types of control packet that may cause CPU overload.

* Use this row to make the setting the same for all entries. Use this row first and then make

adjustments to each entry if necessary.

Changes in this row are copied to all the entries as soon as you make them.

Active Select this option to have the Switch detect if the configured rate limit for a specific control

packet is exceeded and take the action selected below.

Mode Select the action that the Switch takes when the number of control packets exceed the rate

limit on a port, set in the Advanced Application > Errdisable > CPU protection screen.

•inactive-port - The Switch disables the port on which the control packets are received.

•inactive-reason - The Switch drops all the specified control packets (such as BPDU) on the

port.

•rate-limitation - The Switch drops the additional control packets the port(s) has to handle in

every one second.

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31.6 Error-Disable Recovery Configuration

Use this screen to configure the Switch to automatically undo an action after the error is gone. Click the

Click Here link next to Errdisable Recovery in the Advanced Application > Errdisable screen to display

the screen as shown.

Figure 218 Advanced Application > Errdisable > Errdisable Recovery

The following table describes the labels in this screen.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 140 Advanced Application > Errdisable > Errdisable Detect (continued)

LABEL DESCRIPTION

Table 141 Advanced Application > Errdisable > Errdisable Recovery

LABEL DESCRIPTION

Active Select this option to turn on the error-disable recovery function on the Switch.

Reason This field displays the supported features that allow the Switch to shut down a port or discard

packets on a port according to the feature requirements and what action you configure.

* Use this row to make the setting the same for all entries. Use this row first and then make

adjustments to each entry if necessary.

Changes in this row are copied to all the entries as soon as you make them.

Timer Status Select this option to allow the Switch to wait for the specified time interval to activate a port or

allow specific packets on a port, after the error was gone. Deselect this option to turn off this

rule.

Interval Enter the number of seconds (from 30 to 2592000) for the time interval.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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CHAPTER 32

Private VLAN

This chapter shows you how to configure the Switch to prevent communications between ports in a

VLAN.

32.1 Private VLAN Overview

Private VLAN allows you to do port isolation within a VLAN in a simple way. You specify which port(s) in a

VLAN is not isolated by adding it to the promiscuous port list. The Switch automatically adds other ports

in this VLAN to the isolated port list and blocks traffic between the isolated ports. A promiscuous port can

communicate with any port in the same VLAN. An isolated port can communicate with the promiscuous

port(s) only.

Note: You can have up to one private VLAN rule for each VLAN.

Figure 219 Private VLAN Example

Note: Make sure you keep at least one port in the promiscuous port list for a VLAN with private

VLAN enabled. Otherwise, this VLAN is blocked from the whole network.

32.2 Configuring Private VLAN

Click Advanced Application > Private VLAN in the navigation panel to display the screen as shown.

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Figure 220 Advanced Application > Private VLAN

The following table describes the labels in this screen.

Table 142 Advanced Application > Private VLAN

LABEL DESCRIPTION

Active Check this box to enable private VLAN in a VLAN.

Name Enter a descriptive name (up to 32 printable ASCII characters) for identification purposes.

VLAN ID Enter a VLAN ID from 1 to 4094. This is the VLAN to which this rule applies.

Promiscuous Ports Enter the number of the port(s) that can communicate with any ports in the same VLAN.

Other ports belonging to this VLAN will be added to the isolation list and can only send and

receive traffic from the port(s) you specify here.

Add Click Add to insert the entry in the summary table below and save your changes to the

Switch’s run-time memory. The Switch loses these changes if it is turned off or loses power, so

use the Save link on the top navigation panel to save your changes to the non-volatile

memory when you are done configuring.

Cancel Click Cancel to reset the fields to your previous configuration.

Clear Click Clear to clear the fields to the factory defaults.

Index This is the index number of the rule.

Active This shows whether this rule is activated or not.

Name This is the descriptive name for this rule.

VLAN This is the VLAN to which this rule is applied.

Promiscuous Ports This shows the port(s) that can communicate with any ports in the same VLAN.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Check the rule(s) that you want to remove and then click the Delete button.

Cancel Click Cancel to clear the check boxes.

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CHAPTER 33

Green Ethernet

This chapter shows you how to configure the Switch to reduce the power consumed by switch ports.

33.1 Green Ethernet Overview

Green Ethernet reduces switch port power consumption in the following ways.

IEEE 802.3az Energy Efficient Ethernet (EEE)

If EEE is enabled, both sides of a link support EEE and there is no traffic, the port enters Low Power Idle

(LPI) mode. LPI mode turns off some functions of the physical layer (becomes quiet) to save power.

Periodically the port transmits a REFRESH signal to allow the link partner to keep the link alive. When there

is traffic to be sent, a WAKE signal is sent to the link partner to return the link to active mode.

Auto Power Down

Auto Power Down turns off almost all functions of the port’s physical layer functions when the link is

down, so the port only uses power to check for a link up pulse from the link partner. After the link up

pulse is detected, the port wakes up from Auto Power Down and operates normally.

Short Reach

Traditional Ethernet transmits all data with enough power to reach the maximum cable length. Shorter

cables lose less power, so Short Reach saves power by adjusting the transmit power of each port

according to the length of cable attached to that port.

33.2 Configuring Green Ethernet

Click Advanced Application > Green Ethernet in the navigation panel to display the screen as shown.

Note: EEE, Auto Power Down and Short Reach are not supported on an uplink port.

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Figure 221 Advanced Application > Green Ethernet

The following table describes the labels in this screen.

Table 143 Advanced Application > Green Ethernet

LABEL DESCRIPTION

EEE Select this to activate Energy Efficient Ethernet globally.

Auto Power

Down

Select this to activate Auto Power Down globally.

Short Reach Select this to activate Short Reach globally.

Port This field displays the port number. * means all ports.

* Use this row to make the setting the same for all ports. Use this row first and then make

adjustments to each port if necessary.

Changes in this row are copied to all the ports as soon as you make them.

EEE Select this to activate Energy Efficient Ethernet on this port.

Auto Power

Down

Select this to activate Auto Power Down on this port.

Short Reach Select this to activate Short Reach on this port.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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CHAPTER 34

Link Layer Discovery Protocol

(LLDP)

34.1 LLDP Overview

The LLDP (Link Layer Discovery Protocol) is a layer 2 protocol. It allows a network device to advertise its

identity and capabilities on the local network. It also allows the device to maintain and store information

from adjacent devices which are directly connected to the network device. This helps an administrator

discover network changes and perform necessary network reconfiguration and management. The

device information is encapsulated in the LLDPDUs (LLDP data units) in the form of TLV (Type, Length,

Value). Device information carried in the received LLDPDUs is stored in the standard MIB.

The Switch supports these basic management TLVs.

• End of LLDPDU (mandatory)

•Chassis ID (mandatory)

•Port ID (mandatory)

• Time to Live (mandatory)

• Port Description (optional)

• System Name (optional)

• System Description (optional)

• System Capabilities (optional)

• Management Address (optional)

The Switch also supports the IEEE 802.1 and IEEE 802.3 organizationally-specific TLVs.

IEEE 802.1 specific TLVs:

• Port VLAN ID TLV (optional)

• Port and Protocol VLAN ID TLV (optional)

IEEE 802.3 specific TLVs:

• MAC/PHY Configuration/Status TLV (optional)

• Power via MDI TLV (optional, For PoE models only)

• Link Aggregation TLV (optional)

• Maximum Frame Size TLV (optional)

The optional TLVs are inserted between the Time To Live TLV and the End of LLDPDU TLV.

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The next figure demonstrates that the network devices Switches and Routers (S and R) transmit and

receive device information via LLDPDU and the network manager can query the information using

Simple Network Management Protocol (SNMP).

Figure 222 LLDP Overview

34.2 LLDP-MED Overview

LLDP-MED (Link Layer Discovery Protocol for Media Endpoint Devices) is an extension to the standard

LLDP developed by the Telecommunications Industry Association (TIA) TR-41.4 subcommittee which

defines the enhanced discovery capabilities, such as VoIP applications, to enable network

administrators manage their network topology application more efficiently. Unlike the traditional LLDP,

which has some limitations when handling multiple application devices, the LLDP-MED offers display of

accurate physical topology, interoperability of devices, and easy trouble shooting for misconfigured IP

addresses. There are three classes of endpoint devices that the LLDP-MED supports:

Class I: IP Communications Controllers or other communication related servers

Class II: Voice Gateways, Conference Bridges or Media Servers

Class III: IP-Phones, PC-based Softphones, End user Communication Appliances supporting IP Media

The following figure shows that with the LLDP-MED, network connectivity devices (NCD) like Switches

and Routers will transmit LLDP TLV to endpoint device (ED) like IP Phone first (1), to get its device type

and capabilities information, then it will receive that information in LLDP-MED TLV back from endpoint

devices (2), after that the network connectivity devices will transmit LLDP-MED TLV (3) to provision the

endpoint device to such that the endpoint device’s network policy and location identification

information is updated. Since LLDPDU updates status and configuration information periodically,

network managers may check the result of provision via remote status. The remote status is updated by

receiving LLDP-MED TLVs from endpoint devices.

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Figure 223 LLDP-MED Overview

34.3 LLDP Screens

Click Advanced Application > LLDP in the navigation panel to display the screen as shown next.

Figure 224 Advanced Application > LLDP

The following table describes the labels in this screen.

Table 144 Advanced Application > LLDP

LABEL DESCRIPTION

LLDP

LLDP Local

Status Click here to show a screen with the Switch’s LLDP information.

LLDP Remote

Status Click here to show a screen with LLDP information from the neighboring devices.

LLDP

Configuration Click here to show a screen to configure LLDP parameters.

LLDP-MED

Configuration Click here to show a screen to configure LLDP-MED (Link Layer Discovery Protocol for Media

Endpoint Devices) parameters.

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34.4 LLDP Local Status

This screen displays a summary of LLDP status on this Switch. Click Advanced Application > LLDP > LLDP

Local Status to display the screen as shown next.

Figure 225 Advanced Application > LLDP > LLDP Local Status

LLDP-MED

Network Policy Click here to show a screen to configure LLDP-MED (Link Layer Discovery Protocol for Media

Endpoint Devices) network policy parameters.

LLDP-MED

Location Click here to show a screen to configure LLDP-MED (Link Layer Discovery Protocol for Media

Endpoint Devices) location parameters.

Table 144 Advanced Application > LLDP (continued)

LABEL DESCRIPTION

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The following table describes the labels in this screen.

34.4.1 LLDP Local Port Status Detail

This screen displays detailed LLDP status for each port on this Switch. Click Advanced Application > LLDP

> LLDP Local Status and then, click a port number, for example 1 in the local port column to display the

screen as shown next.

Table 145 Advanced Application > LLDP > LLDP Local Status

LABEL DESCRIPTION

Basic TLV

Chassis ID TLV This displays the chassis ID of the local Switch, that is the Switch you’re configuring. The

chassis ID is identified by the chassis ID subtype.

Chassis ID Subtype - this displays how the chassis of the Switch is identified.

Chassis ID - This displays the chassis ID of the local Switch.

System Name

TLV This shows the host name of the Switch.

System

Description TLV This shows the firmware version of the Switch.

System

Capabilities TLV This shows the System Capabilities enabled and supported on the local Switch.

•System Capabilities Supported - Bridge

•System Capabilities Enabled - Bridge

Management

Address TLV The Management Address TLV identifies an address associated with the local LLDP agent

that may be used to reach higher layer entities to assist discovery by network management.

The TLV may also include the system interface number and an object identifier (OID) that are

associated with this management address

This field displays the Management Address settings on the specified port(s).

•Management Address Subtype - ipv4 / all-802

•Interface Number Subtype - unknown

•Interface Number - 0 (not supported)

•Object Identifier - 0 (not supported)

LLDP Port

Information

This displays the local port information.

Local Port This displays the number of the Switch port which receives the LLDPDU from the remote

device. Click a port number to view the detailed LLDP status on this port at LLDP Local Port

Status Detail screen.

Port ID Subtype This indicates how the port ID field is identified.

Port ID This is an alpha-numeric string that contains the specific identifier for the port from which this

LLDPDU was transmitted.

Port Description This shows the port description that the Switch will advertise from this port.

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Figure 226 Advanced Application > LLDP > LLDP Local Status > LLDP Local Port Status Detail

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The following table describes the labels in this screen.

Table 146 Advanced Application > LLDP > LLDP Local Status > LLDP Local Port Status Detail

LABEL DESCRIPTION

Basic TLV These are the Basic TLV flags

Port ID TLV The port ID TLV identifies the specific port that transmitted the LLDP frame.

•Port ID Subtype: This shows how the port is identified.

•Port ID: This is the ID of the port.

Port Description

TLV This displays the local port description.

Dot1 TLV

Port VLAN ID

TLV This displays the VLAN ID sent by the IEEE 802.1 Port VLAN ID TLV.

Port-Protocol

VLAN ID TLV This displays the IEEE 802.1 Port Protocol VLAN ID TLVs, which indicates whether the VLAN is

enabled and supported.

Dot3 TLV

MAC PHY

Configuration &

Status TLV

The MAC/PHY Configuration/Status TLV advertises the bit-rate and duplex capability of the

sending 802.3 node. It also advertises the current duplex and bit-rating of the sending node.

Lastly, it advertises whether these setting were the result of auto-negotiation during link

initiation or manual override.

•AN Supported - Displays if the port supports or does not support auto-negotiation.

•AN Enabled - The current auto-negotiation status of the port.

•AN Advertised Capability - The auto-negotiation capabilities of the port.

•Oper MAU Type - The current Medium Attachment Unit (MAU) type of the port

Link

Aggregation

TLV

The Link Aggregation TLV indicates whether the link is capable of being aggregated,

whether the link is currently in an aggregation, and if in an aggregation, the port

identification of the aggregation.

• Aggregation Capability — The current aggregation capability of the port.

• Aggregation Status — The current aggregation status of the port.

• Aggregation Port ID — The aggregation ID of the current port.

Max Frame Size

TLV This displays the maximum supported frame size in octets.

MED TLV LLDP Media Endpoint Discovery (MED) is an extension of LLDP that provides additional

capabilities to support media endpoint devices. MED enables advertisement and discovery

of network policies, device location discovery to allow creation of location databases, and

information for troubleshooting.

Capabilities TLV This field displays which LLDP-MED TLV are capable to transmit on the Switch.

• Network Policy

• Location

• Extend Power via MDI PSE

• Extend Power via MDI PD

• Inventory Management

Device Type

TLV This is the LLDP-MED device class. The Zyxel Switch device type is:

• Network Connectivity

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34.5 LLDP Remote Status

This screen displays a summary of LLDP status for each LLDP connection to a neighboring Switch. Click

Advanced Application > LLDP > LLDP Remote Status (Click Here) to display the screen as shown next.

Figure 227 Advanced Application > LLDP > LLDP Remote Status

The following table describes the labels in this screen.

Network Policy

TLV This displays a network policy for the specified application.

•Voice

• Voice-Signaling

•Guest-Voice

• Guest-Voice-Signaling

• Softphone-Voice

• Video-Conferencing

•Streaming-Video

• Video-Signaling

Location

Identification

TLV

This shows the location information of a caller by its ELIN (Emergency Location Identifier

Number) or the IETF Geopriv Civic Address based Location Configuration Information (Civic

Address LCI).

•Coordinate-based LCI - latitude, longitude and altitude coordinates of the location

Configuration Information (LCI)

•Civic LCI - IETF Geopriv Civic Address based Location Configuration Information

•ELIN - (Emergency Location Identifier Number)

Table 146 Advanced Application > LLDP > LLDP Local Status > LLDP Local Port Status Detail

LABEL DESCRIPTION

Table 147 Advanced Application > LLDP > LLDP Remote Status

LABEL DESCRIPTION

Index The index number shows the number of remote devices that are connected to the Switch.

Click on an index number to view the detailed LLDP status for this remote device in the LLDP

Remote Port Status Detail screen.

Local Port This is the number of the Switch’s port that received LLDPDU from the remote device.

Chassis ID This displays the chassis ID of the remote device associated with the transmitting LLDP agent.

The chassis ID is identified by the chassis ID subtype. For example, the MAC address of the

remote device.

Port ID This is an alpha-numeric string that contains the specific identifier for the port from which this

LLDPDU was transmitted. The port ID is identified by the port ID subtype.

Port Description This displays a description for the port from which this LLDPDU was transmitted.

System Name This displays the system name of the remote device.

Management

Address

This displays the management address of the remote device. It could be the MAC address or

IP address.

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34.5.1 LLDP Remote Port Status Detail

This screen displays detailed LLDP status of the remote device connected to the Switch. Click Advanced

Application > LLDP > LLDP Remote Status (Click Here) and then click an index number, for example 1, in

the Index column in the LLDP Remote Status screen to display the screen as shown next.

Figure 228 Advanced Application > LLDP > LLDP Remote Status > LLDP Remote Port Status Detail (Basic

TLV)

The following table describes the labels in Basic TLV part of the screen.

Table 148 Advanced Application > LLDP > LLDP Remote Status > LLDP Remote Port Status Detail (Basic

TLV)

LABEL DESCRIPTION

Local Port This displays the number of the Switch’s port to which the remote device is connected.

Basic TLV

Chassis ID TLV • Chassis ID Subtype - this displays how the chassis of the remote device is identified.

•Chassis ID - this displays the chassis ID of the remote device. The chassis ID is identified by

the chassis ID subtype.

Port ID TLV • Port ID Subtype - this displays how the port of the remote device is identified.

•Port ID - this displays the port ID of the remote device. The port ID is identified by the port

ID subtype.

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Time To Live TLV This displays the time-to-live (TTL) multiplier of LLDP frames. The device information on the

neighboring devices ages out and is discarded when its corresponding TTL expires. The TTL

value is to multiply the TTL multiplier by the LLDP frames transmitting interval.

Port Description

TLV This displays the remote port description.

System Name

TLV This displays the system name of the remote device.

System

Description TLV This displays the system description of the remote device.

System

Capabilities TLV This displays whether the system capabilities are enabled and supported on the remote

device.

• System Capabilities Supported

• System Capabilities Enabled

Management

Address TLV This displays the following management address parameters of the remote device.

• Management Address Subtype

• Management Address

• Interface Number Subtype

• Interface Number

• Object Identifier

Port-Protocol

VALN ID TLV This displays the IEEE 802.1 Port Protocol VLAN ID TLV, which indicates whether the VLAN is

enabled and supported.

Table 148 Advanced Application > LLDP > LLDP Remote Status > LLDP Remote Port Status Detail (Basic

TLV)

LABEL DESCRIPTION

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Figure 229 Advanced Application > LLDP > LLDP Remote Status > LLDP Remote Port Status Detail> (Dot

1 and Dot3 TLV)

The following table describes the labels in the Dot1 and Dot3 parts of the screen.

Table 149 Advanced Application > LLDP > LLDP Remote Status > LLDP Remote Port Status Detail (Dot1

and Dot3 TLV)

LABEL DESCRIPTION

Dot1 TLV

Port VLAN ID

TLV This displays the VLAN ID of this port on the remote device.

Port-Protocol

VLAN ID TLV This displays the IEEE 802.1 Port Protocol VLAN ID TLV, which indicates whether the VLAN ID

and whether it is enabled and supported on the port of remote Switch which sent the

LLDPDU.

• Port-Protocol VLAN ID

• Port-Protocol VLAN ID Supported

• Port-Protocol VLAN ID Enabled

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Vlan Name TLV This shows the VLAN ID and name for remote device port.

•VLAN ID

• VLAN Name

Protocol

Identity TLV The Protocol Identity TLV allows the Switch to advertise the particular protocols that are

accessible through its port.

Dot3 TLV

MAC PHY

Configuration &

Status TLV

The MAC/PHY Configuration/Status TLV advertises the bit-rate and duplex capability of the

sending 802.3 node. It also advertises the current duplex and bit-rating of the sending node.

Lastly, it advertises whether these setting were the result of auto-negotiation during link

initiation or manual override.

•AN Supported - Displays if the port supports or does not support auto-negotiation.

•AN Enabled - The current auto-negotiation status of the port.

•AN Advertised Capability - The auto-negotiation capabilities of the port.

•Oper MAU Type - The current Medium Attachment Unit (MAU) type of the port

Link

Aggregation

TLV

The Link Aggregation TLV indicates whether the link is capable of being aggregated,

whether the link is currently in an aggregation, and if in an aggregation, the port

identification of the aggregation.

•Aggregation Capability — The current aggregation capability of the port.

•Aggregation Status — The current aggregation status of the port.

•Aggregation Port ID — The aggregation ID of the current port.

Power Via MDI

TLV The Power Via MDI TLV allows PoE devices to advertise and discover the MDI power support

capabilities of the sending port on the remote device.

•Port Class

• MDI Supported

• MDI Enabled

• Pair Controllable

• PSE Power Pairs

•Power Class

Max Frame Size

TLV This displays the maximum supported frame size in octets.

Table 149 Advanced Application > LLDP > LLDP Remote Status > LLDP Remote Port Status Detail (Dot1

and Dot3 TLV)

LABEL DESCRIPTION

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Figure 230 Advanced Application > LLDP > LLDP Remote Status > LLDP Remote Port Status Detail (MED

TLV)

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The following table describes the labels in the MED TLV part of the screen.

Table 150 Advanced Application > LLDP > LLDP Remote Status > LLDP Remote Port Status Detail (MED

TLV)

LABEL DESCRIPTION

MED TLV LLDP Media Endpoint Discovery (MED) is an extension of LLDP that provides additional

capabilities to support media endpoint devices. MED enables advertisement and discovery

of network policies, device location discovery to allow creation of location databases, and

information for troubleshooting.

Capabilities TLV This displays the MED capabilities the remote port supports.

• Network Policy

• Location

• Extend Power via MDI PSE

• Extend Power via MDI PD

• Inventory Management

Device Type

TLV LLDP-MED endpoint device classes:

• Endpoint Class I

• Endpoint Class II

• Endpoint Class III

• Network Connectivity

Network Policy

TLV This displays a network policy for the specified application.

•Voice

• Voice-Signaling

•Guest-Voice

• Guest-Voice-Signaling

• Softphone-Voice

• Video-Conferencing

•Streaming-Video

• Video-Signaling

Location

Identification

TLV

This shows the location information of a caller by its:

•Coordinate-base LCI - latitude and longitude coordinates of the Location Configuration

Information (LCI)

•Civic LCI - IETF Geopriv Civic Address based Location Configuration Information

•ELIN - (Emergency Location Identifier Number)

Inventory TLV The majority of IP Phones lack support of management protocols such as SNMP, so LLDP-MED

inventory TLVs are used to provide their inventory information to the Network Connectivity

Devices such as the Switch. The Inventory TLV may contain the following information.

• Hardware Revision

• Software Revision

•Firmware Revision

• Model Name

• Manufacturer

• Serial Number

•Asset ID

Extended

Power via MDI

TLV

Extended Power Via MDI Discovery enables detailed power information to be advertised by

Media Endpoints, such as IP phones and Network Connectivity Devices such as the Switch.

•Power Type - whether it is currently operating from primary power or is on backup power

(backup power may indicate to the Endpoint Device that it should move to a power

conservation mode).

•Power Source - whether or not the Endpoint is currently operating from an external power

source.

•Power Priority - the Endpoint Device’s power priority (which the Network Connectivity

Device may use to prioritize which devices will remain in service during power shortages)

•Power Value - power requirement, in fractions of Watts, in current configuration

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34.6 LLDP Configuration

Use this screen to configure global LLDP settings on the Switch. Click Advanced Application > LLDP >

LLDP Configuration (Click Here) to display the screen as shown next.

Figure 231 Advanced Application > LLDP > LLDP Configuration

The following table describes the labels in this screen.

Table 151 Advanced Application > LLDP > LLDP Configuration

LABEL DESCRIPTION

Active Select to enable LLDP on the Switch. It is enabled by default.

Transmit Interval Enter how many seconds the Switch waits before sending LLDP packets.

Transmit Hold Enter the time-to-live (TTL) multiplier of LLDP frames. The device information on the

neighboring devices ages out and is discarded when its corresponding TTL expires. The TTL

value is to multiply the TTL multiplier by the LLDP packets transmitting interval.

Transmit Delay Enter the delay (in seconds) between successive LLDPDU transmissions initiated by value or

status changes in the Switch MIB.

Reinitialize Delay Enter the number of seconds for LLDP to wait before initializing on a port.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Port This displays the Switch’s port number. * means all ports.

* Use this row to make the setting the same for all ports. Use this row first and then make

adjustments to each port if necessary.

Changes in this row are copied to all the ports as soon as you make them.

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34.6.1 Basic TLV Setting

Use this screen to configure Basic TLV settings. Click Advanced Application > LLDP > LLDP Configuration

(Click Here) > Basic TLV Setting to display the screen as shown next.

Figure 232 Advanced Application > LLDP > LLDP Configuration > Basic TLV Setting

The following table describes the labels in this screen.

Admin Status Select whether LLDP transmission and/or reception is allowed on this port.

• Disable - not allowed

• Tx-Only - transmit only

• Rx-Only - receive only

• Tx-Rx - transmit and receive

Notification Select whether LLDP notification is enabled on this port.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 151 Advanced Application > LLDP > LLDP Configuration

LABEL DESCRIPTION

Table 152 Advanced Application > LLDP > LLDP Configuration > Basic TLV Setting

LABEL DESCRIPTION

Port This displays the Switch’s port number. * means all ports.

* Use this row to make the setting the same for all ports. Use this row first and then make

adjustments to each port if necessary.

Changes in this row are copied to all the ports as soon as you make them.

Management

Address

Select the check box(es) to enable or disable the sending of Management Address TLVs on

the port(s).

Port Description Select the check box(es) to enable or disable the sending of Port Description TLVs on the

port(s).

System Capabilities Select the check box(es) to enable or to disable the sending of System Capabilities TLVs on

the port(s).

System Description Select the check box(es) to enable or to disable the sending of System Description TLVs on

the port(s).

System Name Select the check box(es) to enable or to disable the sending of System Name TLVs on the

port(s).

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34.6.2 Org-specific TLV Setting

Use this screen to configure organization-specific TLV settings. Click Advanced Application > LLDP > LLDP

Configuration (Click Here) > Org-specific TLV Setting to display the screen as shown next.

Figure 233 Advanced Application > LLDP > LLDP Configuration> Org-specific TLV Setting

The following table describes the labels in this screen.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 152 Advanced Application > LLDP > LLDP Configuration > Basic TLV Setting

LABEL DESCRIPTION

Table 153 Advanced Application > LLDP > LLDP Configuration > Org-specific TLV Setting

LABEL DESCRIPTION

Port This displays the Switch’s port number. * means all ports.

* Use this row to make the setting the same for all ports. Use this row first and then make

adjustments to each port if necessary.

Changes in this row are copied to all the ports as soon as you make them.

Dot1 TLV

Port- Protocol

VLAN ID Select the check box(es) to enable or disable the sending of IEEE 802.1 Port and Protocol

VLAN ID TLVs on the port(s).

Port VLAN ID Select the check box(es) to enable or disable the sending of IEEE 802.1 Port VLAN ID TLVs on

the port(s). All check boxes in this column are enabled by default.

Link

Aggregation Select the check box(es) to enable or disable the sending of IEEE 802.3 Link Aggregation TLVs

on the port(s).

Dot3 TLV

MAC/PHY Select the check box(es) to enable or disable the sending of IEEE 802.3 MAC/PHY

Configuration/Status TLVs on the port(s). All check boxes in this column are enabled by

default.

Max Frame Size Select the check box(es) to enable or disable the sending of IEEE 802.3 Max Frame Size TLVs

on the port(s).

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34.7 LLDP-MED Configuration

Click Advanced Application > LLDP > LLDP-MED Configuration to display the screen as shown next.

Figure 234 Advanced Application > LLDP > LLDP-MED Configuration

The following table describes the labels in this screen.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 153 Advanced Application > LLDP > LLDP Configuration > Org-specific TLV Setting

LABEL DESCRIPTION

Table 154 Advanced Application > LLDP > LLDP-MED Configuration

LABEL DESCRIPTION

Port This displays the Switch’s port number. Select * to configure all ports simultaneously.

* Use this row to make the setting the same for all ports. Use this row first and then make

adjustments to each port if necessary.

Changes in this row are copied to all the ports as soon as you make them.

Notification

Topology

Change Select to enable LLDP-MED topology change traps on this port.

MED TLV Setting

Location Select to enable transmitting LLDP-MED location TLV.

Network Policy Select to enable transmitting LLDP-MED Network Policy TLV.

Apply Click Apply to save the changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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34.8 LLDP-MED Network Policy

Click Advanced Application > LLDP > LLDP-MED Network Policy (Click Here) to display the screen as

shown next.

Figure 235 Advanced Application > LLDP > LLDP-MED Network Policy

The following table describes the labels in this screen.

Table 155 Advanced Application > LLDP > LLDP-MED Network Policy

LABEL DESCRIPTION

Port Enter the port number to set up the LLDP-MED network policy.

Application Type Select the type of application used in the network policy.

• voice

• voice-signaling

•guest-voice

• guest-voice-signaling

• softphone-voice

• video-conferencing

• streaming-video

• video-signaling

Tag Select to tag or untag in the network policy.

• tagged

• untagged

VLAN Enter the VLAN ID number. It should be from 1 to 4094. For priority tagged frames, enter “0”.

DSCP Enter the DSCP value of the network policy. The value is defined from 0 through 63 with the 0

representing use of the default DSCP value.

Priority Enter the priority value for the network policy.

Add Click Add after finish entering the network policy information. A summary table will list all the

Switch you’ve added.

Cancel Click Cancel to begin entering the information afresh.

Index This field displays the of index number of the network policy. Click an index number to edit

the rule.

Port This field displays the port number of the network policy.

Application Type This field displays the application type of the network policy.

Tag This field displays the Tag Status of the network policy.

VLAN This field displays the VLANID of the network policy.

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34.9 LLDP-MED Location

Click Advanced Application > LLDP > LLDP-MED Location (Click Here) to display the screen as shown

next.

Figure 236 Advanced Application > LLDP > LLDP-MED Location

Priority This field displays the priority value of the network policy.

DSCP This field displays the DSCP value of the network policy.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Check the rules that you want to remove, then click the Delete button.

Cancel Click Cancel to clear the selected check boxes.

Table 155 Advanced Application > LLDP > LLDP-MED Network Policy

LABEL DESCRIPTION

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The following table describes the labels in this screen.

Table 156 Advanced Application > LLDP > LLDP-MED Location

LABEL DESCRIPTION

Port Enter the port number you want to set up the location within the LLDP-MED network.

Location

Coordinates

The LLDP-MED uses geographical coordinates and Civic Address to set the location

information of the remote device. Geographical based coordinates includes latitude,

longitude, altitude and datum. Civic Address includes Country, State, County, City, Street

and other related information.

Latitude Enter the latitude information. The value should be from 0º to 90º. The negative value

represents the South.

•north

•south

Longitude Enter the longitude information. The value should be from 0º to 180º. The negative value

represents the West.

•west

•east

Altitude Enter the altitude information. The value should be from -2097151 to 2097151 in meters or in

floors.

•meters

•floor

Datum Select the appropriate geodetic datum used by GPS.

•WGS84

• NAD83-NAVD88

• NAD83-MLLW

Civic Address Enter the Civic Address by providing information such as Country, State, County, City, Street,

Number, ZIP code and other additional information. Enter at least two field in this

configuration including the Country. The valid length of the Country field is 2 characters and

all other fields are up to 32 characters.

• Country

• State

• County

• City

• Division

• Neighbor

• Street

• Leading-Street-Direction

• Street-Suffix

• Trailing-Street-Suffix

•House-Number

• House-Number-Suffix

• Landmark

• Additional-Location

•Name

•Zip-Code

• Building

•Unit

• Floor

• Room-Number

• Place-Type

• Postal-Community-Name

• Post-Office-Box

• Additional-Code

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ELIN Number Enter a numerical digit string, corresponding to the ELIN identifier which is used during

emergency call setup to a traditional CAMA or ISDN trunk-based PSAP. The valid length is

from 10 to 25 characters.

Add Click Add after finish entering the location information.

Cancel Click Cancel to begin entering the location information afresh.

Index This lists the index number of the location configuration. Click an index number to view or edit

the location.

Port This lists the port number of the location configuration.

Location

Coordinates

This field displays the location configuration information based on geographical coordinates

that includes longitude, latitude, altitude and datum.

Civic Address This field displays the Civic Address for the remote device using information such as Country,

State, County, City, Street, Number, ZIP code and additional information.

ELIN Number This field shows the Emergency Location Identification Number (ELIN), which is used to

identify endpoint devices when they issue emergency call services. The valid length is form

10 to 25 characters.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Check the locations that you want to remove, then click the Delete button.

Cancel Click Cancel to clear the selected check boxes.

Table 156 Advanced Application > LLDP > LLDP-MED Location

LABEL DESCRIPTION

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CHAPTER 35

Anti-Arpscan

35.1 Anti-Arpscan Overview

Address Resolution Protocol (ARP), RFC 826, is a protocol used to convert a network-layer IP address to a

link-layer MAC address. ARP scan is used to scan the network of a certain interface for alive hosts. It

shows the IP address and MAC addresses of all hosts found. Hackers could use ARP scan to find targets

in your network. Anti-arpscan is used to detect unusual ARP scan activity and block suspicious hosts or

ports.

Unusual ARP scan activity is determined by port and host thresholds that you set. A port threshold is

determined by the number of packets received per second on the port. If the received packet rate is

over the threshold, then the port is put into an Err-Disable state. You can recover the normal state of the

port manually if this happens and after you identify the cause of the problem.

A host threshold is determined by the number of ARP-request packets received per second. There is a

global threshold rate for all hosts. If the rate of a host is over the threshold, then that host is blocked by

using a MAC address filter. A blocked host is released automatically after the MAC aging time expires.

Note: A port-based threshold must be larger than the host-based threshold or the host-based

threshold will not work.

35.1.1 What You Can Do

• Use the Anti-Arpscan Status screen (Section 35.2 on page 318) to see what ports are trusted and are

forwarding traffic or are disabled.

• Use the Anti-Arpscan Host Status screen (Section 35.3 on page 318) to view blocked hosts and clear

selected ones.

• Use the Anti-Arpscan Trust Host screen (Section 35.4 on page 319) to create or remove trusted hosts

identified by IP address and subnet mask. Anti-arpscan is not performed on trusted hosts.

• Use this Anti-Arpscan Configure screen (Section 35.5 on page 320) to enable anti-arpscan, set port

and host thresholds as well as configure ports to be trusted or untrusted.

35.1.2 What You Need to Know

• You should set an uplink port as a trusted port before enabling Anti-arpscan so as to prevent the port

from being shutdown due to receiving too many ARP messages.

• When a port is configured as a trusted port, Anti-arpscan is not performed on the port. Both host and

port thresholds are ignored for trusted ports. If the received ARP packet rate on a port or the received

ARP-requests from a host exceed the thresholds, the trusted port will not be closed.

• If a port on the Switch is closed by Anti-arpscan, and you want to recover it, then do one of the

following:

•Go to Basic Setting > Port Setup. Clear Active and click Apply. Then select Active and click Apply

again.

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•Go to Application > Errdiable > Errdisable Recovery and set the interval for Anti-arpscan. After the

interval expires, the closed port(s) will become active and start receiving packets again.

• Use the command port no inactive.

• Refer to the port logs to see when a port was closed.

35.2 Anti-Arpscan Status

Use this screen to see what ports are trusted and are forwarding traffic or are disabled. To open this

screen, click Advanced Application > Anti-Arpscan.

Figure 237 Advanced Application > Anti-Arpscan Status

The following table describes the fields in the above screen.

35.3 Anti-Arpscan Host Status

Use this screen to view blocked hosts and unblock ones connected to certain ports. To open this screen,

click Advanced Application > Anti-Arpscan > Host Status.

Table 157 Advanced Application > Anti-Arpscan Status

LABEL DESCRIPTION

Anti-Arpscan is.... This shows whether Anti-arpscan is enabled or disabled on the Switch.

Port This field displays the port number of the Switch.

Trusted This field displays whether the port is trusted or untrusted. Anti-arpscan is not performed on

a trusted port.

State This field displays whether the port can forward traffic normally (Forwarding) or is disabled

(Err-Disable).

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Figure 238 Advanced Application > Anti-Arpscan > Host Status

The following table describes the fields in the above screen.

35.4 Anti-Arpscan Trust Host

Use this screen to create or remove trusted hosts identified by IP address and subnet mask. Anti-arpscan

is not performed on trusted hosts. To open this screen, click Advanced Application > Anti-Arps can > Trust

Host.

Figure 239 Advanced Application > Anti-Arpscan > Trust Host

The following table describes the fields in the above screen.

Table 158 Advanced Application > Anti-Arpscan > Host Status

LABEL DESCRIPTION

Clear Filtered host: A filtered host is a blocked IP address.

Port List Type a port number or a series of port numbers separated by commas and spaces, and

then click Clear to unblock all hosts connected to these ports.

Filtered host: This table lists information on blocked hosts.

Index This displays the index number of an IP address (a host) that has been blocked.

Host IP This displays the IP address of the blocked host.

MAC This displays the MAC address of the blocked host.

VLAN This displays the VLAN ID that shows which VLAN the blocked host is in.

Port This displays the port number to which the blocked host is connected.

State This shows Err-Disable if the ARP-request rate from this host is over the threshold. Forwarding

hosts are not displayed.

Table 159 Advanced Application > Anti-Arpscan > Trust Host

LABEL DESCRIPTION

Name Type a descriptive name of up to 32 printable ASCII characters to identify this host.

Host IP Type the IP address of the host.

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35.5 Anti-Arpscan Configure

Use this screen to enable Anti-Arpscan, set port and host thresholds as well as configure ports to be

trusted or untrusted. To open this screen, click Advanced Application > Anti-Arpscan > Configure.

Figure 240 Advanced Application > Anti-Arpscan > Configure

Mask A trusted host may consist of a subnet of IP addresses. Type a subnet mask to create a

single host or a subnet of hosts.

Add Click this to create the trusted host.

Cancel Click this to reset the values above based or, if not applicable, to clear the fields above.

Clear Click this to clear the fields above.

Index This field displays a sequential number for each trusted host.

Name This field displays the name of the trusted host.

Host IP This field displays the IP address of the trusted host.

Mask This field displays the subnet mask of the trusted host.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in

the table heading row to select all entries.

Delete Select an entry checkbox and click Delete to remove the specified entry.

Cancel Click this to clear the check boxes above.

Table 159 Advanced Application > Anti-Arpscan > Trust Host

LABEL DESCRIPTION

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The following table describes the fields in the above screen.

Table 160 Advanced Application > Anti-Arpscan > Configure

LABEL DESCRIPTION

Active Select this to enable Anti-arpscan on the Switch.

Port Threshold A port threshold is determined by the number of packets received per second on the port.

If the received packet rate is over the threshold, then the port is put into an Err-Disable

state. Type the maximum number of packets per second allowed on the port before it is

blocked.

Note: The allowed range is 2 to 255 packets received per second.

Host Threshold A host threshold is determined by the number of ARP-request packets received per

second. This is the global threshold rate for all hosts. If the rate of a host is over the

threshold, then that host is blocked by using a MAC address filter. A blocked host is

released automatically after the MAC aging time expires.

Type the maximum number of ARP-request packets allowed by a host before it is blocked.

Note: The allowed range is 2 to 100 ARP-request packets per second.

Note: The port-based threshold must be larger than the host-based threshold or

the host-based threshold will not be applied.

Port This field displays the port number.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to

set the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Trusted State Select Untrusted or Trusted for the associated port. Anti-arpscan is not performed on

trusted hosts.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values in this screen to their last-saved values.

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CHAPTER 36

BPDU Guard

36.1 BPDU Guard Overview

A BPDU (Bridge Protocol Data Units) is a data frame that contains information about STP. STP-aware

switches exchange BPDUs periodically.

The BPDU guard feature allows you to prevent any new STP-aware switch from connecting to an existing

network and causing STP topology changes in the network. If there is any BPDU detected on the port(s)

on which BPDU guard is enabled, the Switch disables the port(s) automatically. You can then enable the

port(s) manually in the Basic Setting > Port Setup screen (Section 8.7 on page 88) or use the Errdisable

Recovery screen (see Section 31.6 on page 290) to have the port(s) become active after a certain time

interval.

36.1.1 What You Can Do

• Use the BPDU Guard Status screen (Section 36.2 on page 322) to view the BPDU guard status.

• Use the BPDU Guard Configuration screen (Section 36.3 on page 323) to enable BPDU guard on the

Switch.

36.2 BPDU Guard Status

Use this screen to view whether BPDU guard is enabled on the Switch and the port status. Click

Advanced Application > BPDU Guard in the navigation panel.

Figure 241 Advanced Application > BPDU Guard Status

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The following table describes the fields in the above screen.

36.3 BPDU Guard Configuration

Use this screen to turn on the BPDU guard feature on the Switch and port(s).

In the BPDU Guard Status screen click Configuration to display the configuration screen as shown.

Figure 242 Advanced Application > BPDU Guard > BPDU Guard Configuration

The following table describes the fields in the above screen.

Table 161 Advanced Application > BPDU Guard Status

LABEL DESCRIPTION

BPDU guard globally

configuration

This field displays whether BPDU guard is activated on the Switch.

Port This field displays the port number.

Active This shows whether BPDU guard is activated on the port.

Status This shows whether the port is shut down (Err-disable) or able to transmit packets

(Forwarding).

Table 162 Advanced Application > BPDU Guard > BPDU Guard Configuration

LABEL DESCRIPTION

Active Select this option to enable BPDU guard on the Switch.

Port This field displays the port number.

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* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select this check box to enable the BPDU guard feature on this port. The Switch shuts down this

port if there is any BPDU received on the port.

Clear this check box to disable the BPDU guard feature.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 162 Advanced Application > BPDU Guard > BPDU Guard Configuration

LABEL DESCRIPTION

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CHAPTER 37

OAM

37.1 OAM Overview

Link layer Ethernet OAM (Operations, Administration and Maintenance) as described in IEEE 802.3ah is a

link monitoring protocol. It utilizes OAM Protocol Data Units or OAM PDUs to transmit link status

information between directly connected Ethernet devices. Both devices must support IEEE 802.3ah.

Because link layer Ethernet OAM operates at layer two of the OSI (Open Systems Interconnection Basic

Reference) model, neither IP or SNMP are necessary to monitor or troubleshoot network connection

problems.

The Switch supports the following IEEE 802.3ah features:

• Discovery - this identifies the devices on each end of the Ethernet link and their OAM configuration.

• Remote Loopback - this can initiate a loopback test between Ethernet devices.

37.1.1 What You Can Do

• Use the OAM Status screen (Section 37.2 on page 325) to view the configuration of ports on which

Ethernet OAM is enabled.

• Use the OAM Configuration screen (Section 37.3 on page 329) to enable Ethernet OAM on the Switch.

• Use the OAM Remote Loopback screen (Section 37.4 on page 331) to perform remote-loopback tests.

37.2 OAM Status

Use this screen to view the configuration of ports on which Ethernet OAM is enabled. Click Advanced

Application > OAM in the navigation panel.

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Figure 243 Advanced Application > OAM Status

The following table describes the fields in the above screen.

37.2.1 OAM Details

Use this screen to view OAM configuration details and operational status of a specific port. Click a

number in the Port column in the OAM Status screen to display the screen as shown next.

Table 163 Advanced Application > OAM Status

LABEL DESCRIPTION

Local

This section displays information about the ports on the Switch.

Port This field displays the port number.

Mode This field displays the operational state of the port when OAM is enabled on the port.

Active - Allows the port to issue and respond to Ethernet OAM commands.

Passive - Allows the port to respond to Ethernet OAM commands.

Remote

This section displays information about the remote device.

Mac Address This field displays the MAC address of the remote device.

OUI This field displays the OUI (first three bytes of the MAC address) of the remote device.

Mode This field displays the operational state of the port when OAM is enabled on the port.

Active - Allows the port to issue and respond to Ethernet OAM commands.

Passive - Allows the port to respond to Ethernet OAM commands.

Config This field displays the capabilities of the Switch and remote device.

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Figure 244 Advanced Application > OAM Status > OAM Details

The following table describes the fields in the above screen.

Table 164 Advanced Application > OAM Status > OAM Details

LABEL DESCRIPTION

Discovery This section displays OAM configuration details and operational status of the port on the

Switch and/or the remote device.

Local Client/Remote Client

OAM configurations

Mode This field displays the OAM mode. The device in active mode (typically the service

provider's device) controls the device in passive mode (typically the subscriber's device).

Active: The port initiates OAM discovery; sends information PDUs; and may send event

notification PDUs, variable request/response PDUs, or loopback control PDUs.

Passive: The port waits for the remote device to initiate OAM discovery; sends information

PDUs; may send event notification PDUs; and may respond to variable request PDUs or

loopback control PDUs.

The Switch might not support some types of PDUs, as indicated in the fields below.

Unidirectional This field indicates whether or not the port can send information PDUs to transmit fault

information when the receive path is non-operational.

Remote loopback This field indicates whether or not the port can use loopback control PDUs to put the

remote device into loopback mode.

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Link events This field indicates whether or not the port can interpret link events, such as link fault and

dying gasp. Link events are sent in event notification PDUs and indicate when the number

of errors in a given interval (time, number of frames, number of symbols, or number of

errored frame seconds) exceeds a specified threshold. Organizations may create

organization-specific link event TLVs as well.

Variable retrieval This field indicates whether or not the port can respond to requests for more information,

such as requests for Ethernet counters and statistics, about link events.

Max. OAMPDU

size This field displays the maximum size of PDU for receipt and delivery.

Local Client/Remote Client

Operational status

Link status This field indicates that the link between the Switch port and a connected IEEE 802.3ah-

enabled remote Ethernet device is up or down.

Info. revision This field displays the current version of local state and configuration. This two-octet value

starts at zero and increments every time the local state or configuration changes.

Parser state This field indicates the current state of the parser.

Forward: The port is forwarding packets normally.

Loopback: The port is in loopback mode.

Discard: The port is discarding non-OAM PDUs because it is trying to or has put the remote

device into loopback mode.

Discovery

state This field indicates the state in the OAM discovery process. OAM-enabled devices use this

process to detect each other and to exchange information about their OAM

configuration and capabilities. OAM discovery is a handshake protocol.

Fault: One of the devices is transmitting OAM PDUs with link fault information, or the

interface is not operational.

Active Send Local: The port is in active mode and is trying to see if the remote device

supports OAM.

Passive Wait: The port is in passive mode and is waiting for the remote device to begin

OAM discovery.

Send Local Remote: This state occurs in the following circumstances.

• The port has discovered the remote device but has not accepted or rejected the

connection yet.

• The port has discovered the remote device and rejected the connection.

Send Local Remote OK: The port has discovered the remote device and has accepted the

connection. In addition, the remote device has not accepted or rejected the connection

yet, or the remote device has rejected the connected.

Send Any: The port and the remote device have accepted the connection. This is the

operating state for OAM links that are fully operational.

Remote Client

MAC Address This field displays the MAC address of the IEEE 802.3ah-enabled remote Ethernet device

that is connected to the Switch.

Vendor(oui) This field displays the Organizationally Unique Identifiers (OUI) representing the vendor of

the IEEE 802.3ah-enabled remote Ethernet device that is connected to the Switch.

Statistics

This section displays the number of OAM packets transferred on the port of the Switch.

Information OAMPDU

This field displays the number of OAM PDUs sent on the port.

Table 164 Advanced Application > OAM Status > OAM Details

LABEL DESCRIPTION

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37.3 OAM Configuration

Use this screen to turn on Ethernet OAM on the Switch and port(s) and configure the related settings.

In the OAM Status screen click Configuration to display the configuration screen as shown.

Information OAMPDU

This field displays the number of OAM PDUs received on the port.

Event Notification

OAMPDU Tx

This field displays the number of unique or duplicate OAM event notification PDUs sent on

the port.

Event Notification

OAMPDU Rx

This field displays the number of unique or duplicate OAM event notification PDUs received

on the port.

Loopback Control

OAMPDU Tx

This field displays the number of loopback control OAM PDUs sent on the port.

Loopback Control

OAMPDU Rx

This field displays the number of loopback control OAM PDUs received on the port.

Variable Request

OAMPDU Tx

This field displays the number of OAM PDUs sent to request MIB objects on the remote

device.

Variable Request

OAMPDU Rx

This field displays the number of OAM PDUs received requesting MIB objects on the Switch.

Variable Response

OAMPDU Tx

This field displays the number of OAM PDUs sent by the Switch in response to requests.

Variable Response

OAMPDU Rx

This field displays the number of OAM PDUs sent by the remote device in response to

requests.

Unsupported

OAMPDU Tx

This field displays the number of unsupported OAM PDUs sent on the port.

Unsupported

OAMPDU Rx

This field displays the number of unsupported OAM PDUs received on the port.

Table 164 Advanced Application > OAM Status > OAM Details

LABEL DESCRIPTION

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Figure 245 Advanced Application > OAM > OAM Configuration

The following table describes the fields in the above screen.

Table 165 Advanced Application > OAM > OAM Configuration

LABEL DESCRIPTION

Active Select this option to enable Ethernet OAM on the Switch.

Port This field displays the port number.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to

set the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select this check box to enable Ethernet OAM on this port.

Clear this check box to disable Ethernet OAM on the port.

Mode Specify the OAM mode on the port.

Select Active to allow the port to issue and respond to Ethernet OAM commands.

Select Passive to allow the port to respond to Ethernet OAM commands.

Remote Loopback

Supported

Select this check box to enable the remote loopback feature on the port. Otherwise, clear

the check box to disable it.

Remote Loopback

Ignore-Rx

Select this check box to set the Switch to process loopback commands received on the

port. Otherwise, clear the check box to have the Switch ignore loopback commands

received on the port.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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37.4 OAM Remote Loopback

Use this screen to perform a remote-loopback test. In the OAM Status screen click Remote Loopback to

display the screen as shown.

Figure 246 Advanced Application > OAM > OAM Remote Loopback

The following table describes the fields in the above screen.

Table 166 Advanced Application > OAM > OAM Remote Loopback

LABEL DESCRIPTION

Remote Loopback Test

Port Enter the number of the port from which the Switch performs a remote-loopback test.

Number of

Packet Define the allowable packet number of the loopback test frames.

Packet Size Define the allowable packet size of the loopback test frames.

Test Click Test to begin the test.

Remote Loopback Mode

Port Enter the number of the port from which the Switch sends loopback control PDUs to initiate

or terminate a remote-loopback test.

Start Click Start to initiate a remote-loopback test from the specified port by sending Enable

Loopback Control PDUs to the remote device.

Stop Click Stop to terminate a remote-loopback test from the specified port by sending Disable

Loopback Control PDUs to the remote device.

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CHAPTER 38

ZULD

38.1 ZULD Overview

A unidirectional link is a connection where the link is up on both ends, but only one end can receive

packets. This may happen if OAM was initially enabled but then disabled, there are misconfigured

transmitting or receiving lines or the hardware is malfunctioning. Zyxel Unidirectional Link Detection

(ZULD) is a layer-2 protocol that can detect and disable these physical one-way links before they cause

loops or communication malfunction.

In the figure below, S1 - A is a bidirectional link as both ends can send packets to each other. S1-B is

unidirectional as B cannot send packets to S1 (although the S1-B link is up). Similarly, S2-S1 is

unidirectional as S1 cannot send packets to S2 (although the S1-S2 link is up).

Figure 247 ZULD Overview

38.1.1 What You Can Do

• Use the ZULD Status screen (Section 38.2 on page 333) to see details on ZULD.

• Use the ZULD Configuration screen (Section 38.3 on page 334) to enable ZULD on a port, configure a

mode and set the probe time.

38.1.2 What You Need to Know

• ZULD must be enabled on the Switch and the port(s) in order to detect unidirectional links by

monitoring OAMPDUs.

• Ports advertise their unidirectional link detection capability using OAMPDUs, so all connected devices

must support OAM as well as ZULD. You need to enable OAM on the Switch by going to Advanced

Application > OAM > Configuration and selecting Active. OAM must be enabled on other connected

devices too. If OAM is not enabled initially, ZULD will not work.

• If OAM is enabled initially and later disabled on one end of a link, the link will be unidirectional as that

end cannot send OAMPDUs.

• OAM discovery, the sending of OAMPDUs to other ports, is initiated by an active port.

• When ZULD detects a unidirectional link, it sends a syslog and SNMP trap and may shut down the

affected port (Aggressive Mode).

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• If a port on the Switch is shut down by ZULD, and you want to recover it, then do one of the following:

•Go to Basic Setting > Port Setup. Clear Active and click Apply. Then select Active and click Apply

again.

•Go to Application > Errdiable > Errdisable Recovery and set the interval for ZULD. After the interval

expires, the closed port(s) will become active and start receiving packets again.

• Use the command port no inactive.

• Refer to the ZULD logs to see when a unidirectional link is detected and when it is recovered to a

bidirectional link.

38.2 ZULD Status

Use this screen to see details of unidirectional and bidirectional links discovered by ZULD. To open this

screen, click Advanced Application > ZULD.

Figure 248 Advanced Application > ZULD Status

The following table describes the fields in the above screen.

Table 167 Advanced Application > ZULD Status

LABEL DESCRIPTION

ZULD is.... This shows whether ZULD is enabled or disabled on the Switch.

Port This field displays the port number.

Active This field displays whether ZULD is enabled on the port or not. ZULD must be enabled to

detect an unidirectional link by monitoring OAMPDUs.

Mode This field indicates what ZULD will do when a unidirectional link is detected. In Normal

mode, ZULD only sends a syslog and trap when it detects a unidirectional link. In

Aggressive mode, ZULD shuts down the port (puts it into an ErrDisable state) as well as

sends a syslog and trap when it detects a unidirectional link.

Probe Time Probe time is the length of time that ZULD waits before declaring that a link is

unidirectional. When the probe time expires, and one port (either on the Switch or the

connected device) still has not received an OAMPDU, then ZULD declares that the link is

unidirectional.

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38.3 ZULD Configuration

Use this screen to enable ZULD on a port, configure a mode and set the probe time. To open this screen,

click Advanced Application > ZULD > Configuration.

Figure 249 Advanced Application > ZULD > Configuration

Link State This field shows the following link states:

•Linkdown: This is an initialization state, where the port is not yet up.

•Probe: This indicates that ZULD is discovering the connected device on this link.

•Bidirectional: Traffic sent by the Switch is received by the connected device on this

link, and traffic from the connected device on this link is received by the Switch.

•Unidirectional: The state of the link between the port and its connected port cannot

be determined either because no ZULD message was received, or one port is not

capable of sending traffic.

•Shutdown: The port has been shut down because its link with the connected device is

unidirectional and ZULD is in Aggressive mode.

Remote Operation This field displays whether ZULD is enabled or disabled on the connected device on this

link. ZULD must be enabled on the connected device and on the port that’s connecting to

the Switch.

Remote MAC Addr This is the MAC address of the port on the connected device to which the port of the

Switch is connected.

Remote Port This is the port number of the port on the connected device to which the port of the Switch

is connected.

Table 167 Advanced Application > ZULD Status

LABEL DESCRIPTION

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The following table describes the fields in the above screen.

Table 168 Advanced Application > ZULD > Configuration

LABEL DESCRIPTION

Active Select this to enable ZULD on the Switch.

Port This field displays the port number.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to

set the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select this to enable ZULD on the port. ZULD must be enabled to detect an unidirectional

link by monitoring OAMPDUs.

Mode Select Normal or Aggressive. In Normal mode, ZULD only sends a syslog and trap when it

detects a unidirectional link. In Aggressive mode, ZULD shuts down the port (puts it into an

ErrDisable state) as well as sends a syslog and trap when it detects a unidirectional link.

Probe Time Type the length of time that ZULD waits before declaring that a link is unidirectional. When

the probe time expires, and one port (either on the Switch or the connected device) still

has not received an OAMPDU, then ZULD declares that the link is unidirectional.

The allowed time range is from 5-65535 seconds.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values in this screen to their last-saved values.

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CHAPTER 39

Static Route

39.1 Static Routing Overview

This chapter shows you how to configure static routes.

The Switch uses IP for communication with management computers, for example using HTTP, Telnet, SSH,

or SNMP. Use IP static routes to have the Switch respond to remote management stations that are not

reachable through the default gateway. The Switch can also use static routes to send data to a server

or device that is not reachable through the default gateway, for example when sending SNMP traps or

using ping to test IP connectivity.

This figure shows a Telnet session coming in from network N1. The Switch sends reply traffic to default

gateway R1 which routes it back to the manager’s computer. The Switch needs a static route to tell it to

use router R2 to send traffic to an SNMP trap server on network N2.

Figure 250 Static Routing Overview

39.1.1 What You Can Do

• Use the Static Routing screen (Section 39.2 on page 337) to display the link to the IPv4 Static Route

screen.

• Use the IPv4 Static Route screen (Section 39.3 on page 337) to configure and enable an IPv4 static

route.

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39.2 Static Routing

Click IP Application > Static Routing in the navigation panel to display the screen as shown. Click the link

next to IPv4 Static Route to open a screen where you can create IPv4 static routing rules.

Figure 251 IP Application > Static Routing

39.3 IPv4 Static Route

Click the link next to IPv4 Static Route in the IP Application > Static Routing screen to display the screen

as shown.

Figure 252 IP Application > Static Routing > IPv4 Static Route

The following table describes the related labels you use to create a static route.

Table 169 IP Application > Static Routing > IPv4 Static Route

LABEL DESCRIPTION

Active This field allows you to activate/deactivate this static route.

Name Enter a descriptive name (up to 10 printable ASCII characters) for identification purposes.

Destination IP

Address

This parameter specifies the IP network address of the final destination.

IP Subnet Mask Enter the subnet mask for this destination. Routing is always based on network number. If you

need to specify a route to a single host, use a subnet mask of 255.255.255.255 in the subnet mask

field to force the network number to be identical to the host ID.

Gateway IP

Address

Enter the IP address of the gateway. The gateway is an immediate neighbor of your Switch that

will forward the packet to the destination. The gateway must be a router on the same segment

as your Switch.

Metric The metric represents the “cost” of transmission for routing purposes. IP routing uses hop count as

the measurement of cost, with a minimum of 1 for directly connected networks. Enter a number

that approximates the cost for this link. The number need not be precise, but it must be between

1 and 15. In practice, 2 or 3 is usually a good number.

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Add Click Add to insert a new static route to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the above fields to your previous configuration.

Clear Click Clear to set the above fields back to the factory defaults.

Index This field displays the index number of the route. Click a number to edit the static route entry.

Active This field displays Yes when the static route is activated and NO when it is deactivated.

Name This field displays the descriptive name for this route. This is for identification purposes only.

Destination

Address

This field displays the IP network address of the final destination.

Subnet Mask This field displays the subnet mask for this destination.

Gateway

Address

This field displays the IP address of the gateway. The gateway is an immediate neighbor of your

Switch that will forward the packet to the destination.

Metric This field displays the cost of transmission for routing purposes.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Click Delete to remove the selected entry from the summary table.

Cancel Click Cancel to clear the check boxes.

Table 169 IP Application > Static Routing > IPv4 Static Route

LABEL DESCRIPTION

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CHAPTER 40

Differentiated Services

This chapter shows you how to configure Differentiated Services (DiffServ) on the Switch.

40.1 DiffServ Overview

Quality of Service (QoS) is used to prioritize source-to-destination traffic flows. All packets in the flow are

given the same priority. You can use CoS (class of service) to give different priorities to different packet

types.

DiffServ is a class of service (CoS) model that marks packets so that they receive specific per-hop

treatment at DiffServ-compliant network devices along the route based on the application types and

traffic flow. Packets are marked with DiffServ Code Points (DSCPs) indicating the level of service desired.

This allows the intermediary DiffServ-compliant network devices to handle the packets differently

depending on the code points without the need to negotiate paths or remember state information for

every flow. In addition, applications do not have to request a particular service or give advanced

notice of where the traffic is going.

40.1.1 DSCP and Per-Hop Behavior

DiffServ defines a new DS (Differentiated Services) field to replace the Type of Service (ToS) field in the IP

header. The DS field contains a 6-bit DSCP field which can define up to 64 service levels and the

remaining 2 bits are defined as currently unused (CU). The following figure illustrates the DS field.

Figure 253 DiffServ: Differentiated Service Field

DSCP is backward compatible with the three precedence bits in the ToS octet so that non-DiffServ

compliant, ToS-enabled network device will not conflict with the DSCP mapping.

The DSCP value determines the PHB (Per-Hop Behavior), that each packet gets as it is forwarded across

the DiffServ network. Based on the marking rule different kinds of traffic can be marked for different

priorities of forwarding. Resources can then be allocated according to the DSCP values and the

configured policies.

40.1.2 DiffServ Network Example

The following figure depicts a DiffServ network consisting of a group of directly connected DiffServ-

compliant network devices. The boundary node (A in Figure 254) in a DiffServ network classifies (marks

with a DSCP value) the incoming packets into different traffic flows (Platinum, Gold, Silver, Bronze)

based on the configured marking rules. A network administrator can then apply various traffic policies to

the traffic flows. For example, one traffic policy would be to give higher drop precedence to one traffic

DSCP (6 bits) CU (2 bits)

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flow over others. In our example packets in the Bronze traffic flow are more likely to be dropped when

congestion occurs than the packets in the Platinum traffic flow as they move across the DiffServ

network.

Figure 254 DeffServ Network

40.2 Activating DiffServ

Activate DiffServ to apply marking rules or IEEE 802.1p priority mapping on the selected port(s).

Click IP Application > DiffServ in the navigation panel to display the screen as shown.

Figure 255 IP Application > DiffServ

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The following table describes the labels in this screen.

40.3 DSCP Settings

You can configure the DSCP to IEEE 802.1p mapping to allow the Switch to prioritize all traffic based on

the incoming DSCP value according to the DiffServ to IEEE 802.1p mapping table.

The following table shows the default DSCP-to-IEEE802.1p mapping.

40.3.1 Configuring DSCP Settings

To change the DSCP-IEEE 802.1p mapping, click the DSCP Setting link in the DiffServ screen to display the

screen as shown next.

Figure 256 IP Application > DiffServ > DSCP Setting

Table 170 IP Application > DiffServ

LABEL DESCRIPTION

Active Select this option to enable DiffServ on the Switch.

Port This field displays the port number.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Note: Changes in this row are copied to all the ports as soon as you make them.

Active Select Active to enable DiffServ on the port.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 171 Default DSCP-IEEE 802.1p Mapping

DSCP VALUE 0 – 7 8 – 15 16 – 23 24 – 31 32 – 39 40 – 47 48 – 55 56 – 63

IEEE 802.1p01234567

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The following table describes the labels in this screen.

Table 172 IP Application > DiffServ > DSCP Setting

LABEL DESCRIPTION

0 … 63 This is the DSCP classification identification number.

To set the IEEE 802.1p priority mapping, select the priority level from the drop-down list box.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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CHAPTER 41

DHCP

41.1 DHCP Overview

This chapter shows you how to configure the DHCP feature.

DHCP (Dynamic Host Configuration Protocol RFC 2131 and RFC 2132) allows individual computers to

obtain TCP/IP configuration at start-up from a server. If you configure the Switch as a DHCP relay agent,

then the Switch forwards DHCP requests to DHCP server on your network. If you don’t configure the

Switch as a DHCP relay agent then you must have a DHCP server in the broadcast domain of the client

computers or else the client computers must be configured manually.

41.1.1 What You Can Do

• Use the DHCPv4 Status screen (Section 41.3 on page 344) to display the relay mode.

• Use the DHCPv4 Relay screen (Section 41.4 on page 344) to enable and configure global DHCPv4

relay.

• Use the VLAN Setting screen (Section 41.4.6 on page 349) to configure your DHCPv4 settings based on

the VLAN domain of the DHCPv4 clients.

• Use the DHCPv6 Relay screen (Section 41.5 on page 352) to enable and configure DHCPv6 relay.

41.1.2 What You Need to Know

Read on for concepts on DHCP that can help you configure the screens in this chapter.

DHCP Modes

If there is already a DHCP server on your network, then you can configure the Switch as a DHCP relay

agent. When the Switch receives a request from a computer on your network, it contacts the DHCP

server for the necessary IP information, and then relays the assigned information back to the computer.

DHCPv4 Configuration Options

The DHCPv4 configuration on the Switch is divided into Global and VLAN screens. The screen you should

use for configuration depends on the DHCP services you want to offer the DHCP clients on your network.

Choose the configuration screen based on the following criteria:

•Global - The Switch forwards all DHCP requests to the same DHCP server.

•VLAN - The Switch is configured on a VLAN by VLAN basis. The Switch can be configured to relay

DHCP requests to different DHCP servers for clients in different VLAN.

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41.2 DHCP Configuration

Click IP Application > DHCP in the navigation panel to display the screen as shown. Click the link next to

DHCPv4 to open screens where you can enable and configure DHCPv4 relay settings and create option

82 profiles. Click the link next to DHCPv6 to open a screen where you can configure DHCPv6 relay

settings.

Figure 257 IP Application > DHCP

41.3 DHCPv4 Status

Click IP Application > DHCP > DHCPv4 in the navigation panel. The DHCP Status screen displays.

Figure 258 IP Application > DHCP > DHCPv4

The following table describes the labels in this screen.

41.4 DHCPv4 Relay

Configure DHCP relay on the Switch if the DHCP clients and the DHCP server are not in the same

broadcast domain. During the initial IP address leasing, the Switch helps to relay network information

(such as the IP address and subnet mask) between a DHCP client and a DHCP server. Once the DHCP

client obtains an IP address and can connect to the network, network information renewal is done

between the DHCP client and the DHCP server without the help of the Switch.

The Switch can be configured as a global DHCP relay. This means that the Switch forwards all DHCP

requests from all domains to the same DHCP server. You can also configure the Switch to relay DHCP

information based on the VLAN membership of the DHCP clients.

Table 173 IP Application > DHCP > DHCPv4

LABEL DESCRIPTION

Relay

Status

This section displays configuration settings related to the Switch’s DHCP relay mode.

Relay

Mode

This field displays:

None - if the Switch is not configured as a DHCP relay agent.

Global - if the Switch is configured as a DHCP relay agent only.

VLAN - followed by a VLAN ID or multiple VLAN IDs if it is configured as a relay agent for specific

VLAN(s).

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41.4.1 DHCPv4 Relay Agent Information

The Switch can add information about the source of client DHCP requests that it relays to a DHCP server

by adding Relay Agent Information. This helps provide authentication about the source of the requests.

The DHCP server can then provide an IP address based on this information. Please refer to RFC 3046 for

more details.

The DHCP Relay Agent Information feature adds an Agent Information field (also known as the Option

82 field) to DHCP requests. The Option 82 field is in the DHCP headers of client DHCP request frames that

the Switch relays to a DHCP server.

Relay Agent Information can include the System Name of the Switch if you select this option. You can

change the System Name in Basic Settings > General Setup.

The following describes the DHCP relay agent information that the Switch sends to the DHCP server:

41.4.1.1 DHCPv4 Relay Agent Information Format

A DHCP Relay Agent Information option has the following format.

i1, i2 and iN are DHCP relay agent sub-options, which contain additional information about the DHCP

client. You need to define at least one sub-option.

41.4.1.2 Sub-Option Format

There are two types of sub-option: “Agent Circuit ID Sub-option” and “Agent Remote ID Sub-option”.

They have the following formats.

The 1 in the first field identifies this as an Agent Circuit ID sub-option and 2 identifies this as an Agent

Remote ID sub-option. The next field specifies the length of the field.

Table 174 Relay Agent Information

FIELD LABELS DESCRIPTION

Slot ID (1 byte) This value is always 0 for stand-alone switches.

Port ID (1 byte) This is the port that the DHCP client is connected to.

VLAN ID (2 bytes) This is the VLAN that the port belongs to.

Information (up to 64 bytes) This optional, read-only field is set according to system name set in Basic

Settings > General Setup.

Table 175 DHCP Relay Agent Information Option Format

Code

(82)

Length

(N)

i1 i2

...

Table 176 DHCP Relay Agent Circuit ID Sub-option Format

SubOpt Code Length Value

(1 byte)

Slot ID, Port ID, VLAN ID, System Name or String

Table 177 DHCP Relay Agent Remote ID Sub-option Format

SubOpt Code Length Value

(1 byte)

MAC Address or String

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41.4.2 DHCPv4 Option 82 Profile

Use this screen to create DHCPv4 option 82 profiles. Click IP Application > DHCP > DHCPv4 in the

navigation panel and click the Option 82 Profile link to display the screen as shown.

Figure 259 IP Application > DHCP > DHCPv4 > Option 82 Profile

The following table describes the labels in this screen.

Table 178 IP Application > DHCP > DHCPv4 > Option 82 Profile

LABEL DESCRIPTION

Name Enter a descriptive name for the profile for identification purposes. You can use up to 32 ASCII

characters. Spaces are allowed.

Circuit-ID Use this section to configure the Circuit ID sub-option to include information that is specific to

the relay agent (the Switch).

Enable Select this option to have the Switch add the Circuit ID sub-option to client DHCP requests that it

relays to a DHCP server.

slot-port Select this option to have the Switch add the number of port that the DHCP client is connected

to.

vlan Select this option to have the Switch add the ID of VLAN which the port belongs to.

hostname This is the system name you configure in the Basic Setting > General Setup screen.

Select this option for the Switch to add the system name to the client DHCP requests that it

relays to a DHCP server.

string Enter a string of up to 64 ASCII characters that the Switch adds into the client DHCP requests.

Spaces are allowed.

Remote-ID Use this section to configure the Remote ID sub-option to include information that identifies the

relay agent (the Switch).

Enable Select this option to have the Switch append the Remote ID sub-option to the option 82 field of

DHCP requests.

mac Select this option to have the Switch add its MAC address to the client DHCP requests that it

relays to a DHCP server.

string Enter a string of up to 64 ASCII characters for the remote ID information in this field. Spaces are

allowed.

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41.4.3 Configuring DHCPv4 Global Relay

Use this screen to configure global DHCPv4 relay. Click IP Application > DHCP > DHCPv4 in the

navigation panel and click the Global link to display the screen as shown.

Figure 260 IP Application > DHCP > DHCPv4 > Global

The following table describes the labels in this screen.

Add Click this to create a new entry or to update an existing one.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your changes

to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to their last saved values.

Profile Name This field displays the descriptive name of the profile. Click the name to change the settings.

Circuit-ID

Enable This field displays whether the Circuit ID sub-option is added to client DHCP requests.

Field This field displays the information that is included in the Circuit ID sub-option.

Remote-ID

Enable This field displays whether the Remote ID sub-option is added to client DHCP requests.

Field This field displays the information that is included in the Remote ID sub-option.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Check the entry(ies) that you want to remove and then click the Delete button.

Cancel Click Cancel to clear the selected check box(es).

Table 178 IP Application > DHCP > DHCPv4 > Option 82 Profile (continued)

LABEL DESCRIPTION

Table 179 IP Application > DHCP > DHCPv4 > Global

LABEL DESCRIPTION

Active Select this check box to enable DHCPv4 relay.

Remote DHCP

Server 1 .. 3

Enter the IP address of a DHCPv4 server in dotted decimal notation.

Option 82 Profile Select a pre-defined DHCPv4 option 82 profile that the Switch applies to all ports. The Switch

adds the Circuit ID sub-option and/or Remote ID sub-option specified in the profile to DHCP

requests that it relays to a DHCP server.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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41.4.4 DHCPv4 Global Relay Port Configure

Use this screen to apply a different DHCP option 82 profile to certain ports on the Switch. To open this

screen, click IP Application > DHCP > DHCPv4 > Global > Port.

Figure 261 IP Application > DHCP > DHCPv4 > Global > Port

The following table describes the labels in this screen.

Table 180 IP Application > DHCP > DHCPv4 > Global > Port

LABEL DESCRIPTION

Port Enter the number of port(s) to which you want to apply the specified DHCP option 82 profile.

You can enter multiple ports separated by (no space) comma (,) or hyphen (-). For example,

enter “3-5” for ports 3, 4, and 5. Enter “3,5,7” for ports 3, 5, and 7.

Option 82 Profile Select a pre-defined DHCP option 82 profile that the Switch applies to the specified port(s). The

Switch adds the Circuit ID sub-option and/or Remote ID sub-option specified in the profile to

DHCP requests that it relays to a DHCP server.

The profile you select here has priority over the one you select in the DHCP > DHCPv4 > Global

screen.

Add Click this to create a new entry or to update an existing one.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your changes

to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values above based on the last selected entry or, if not applicable, to

clear the fields above.

Clear Click Clear to reset the fields to the factory defaults.

Index This field displays a sequential number for each entry. Click an index number to change the

settings.

Port This field displays the port(s) to which the Switch applies the settings.

Profile Name This field displays the DHCP option 82 profile that the Switch applies to the port(s).

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Select the entry(ies) that you want to remove, then click the Delete button to remove the

selected entry(ies) from the table.

Cancel Click this to clear the check boxes above.

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41.4.5 Global DHCP Relay Configuration Example

The follow figure shows a network example where the Switch is used to relay DHCP requests for the

VLAN1 and VLAN2 domains. There is only one DHCP server that services the DHCP clients in both

domains.

Figure 262 Global DHCP Relay Network Example

Configure the DHCP Relay screen as shown. Make sure you select a DHCP option 82 profile (default1 in

this example) to set the Switch to send additional information (such as the VLAN ID) together with the

DHCP requests to the DHCP server. This allows the DHCP server to assign the appropriate IP address

according to the VLAN ID.

Figure 263 DHCP Relay Configuration Example

41.4.6 Configuring DHCP VLAN Settings

Use this screen to configure your DHCP settings based on the VLAN domain of the DHCP clients. Click IP

Application > DHCP > DHCPv4 in the navigation panel, then click the VLAN link In the DHCP Status screen

that displays.

Note: You must set up a management IP address for each VLAN that you want to configure

DHCP settings for on the Switch. See Section 5.1.3 on page 61 for information on how to

do this.

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Figure 264 IP Application > DHCP > DHCPv4 > VLAN

The following table describes the labels in this screen.

41.4.7 DHCPv4 VLAN Port Configure

Use this screen to apply a different DHCP option 82 profile to certain ports in a VLAN. To open this screen,

click IP Application > DHCP > DHCPv4 > VLAN > Port.

Table 181 IP Application > DHCP > DHCPv4 > VLAN

LABEL DESCRIPTION

VID Enter the ID number of the VLAN to which these DHCP settings apply.

Relay Use this section if you want to configure the Switch to function as a DHCP relay for this VLAN.

Remote DHCP

Server 1 .. 3

Enter the IP address of a DHCP server in dotted decimal notation.

Option 82 Profile Select a pre-defined DHCP option 82 profile that the Switch applies to all ports in this VLAN. The

Switch adds the Circuit ID sub-option and/or Remote ID sub-option specified in the profile to

DHCP requests that it relays to a DHCP server.

Add Click this to create a new entry or to update an existing one.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your changes

to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Clear Click Clear to reset the fields to the factory defaults.

VID This field displays the ID number of the VLAN group to which this DHCP settings apply.

Type This field displays Relay for the DHCP mode.

DHCP Status For DHCP server configuration, this field displays the starting IP address and the size of the IP

address pool.

For DHCP relay configuration, this field displays the first remote DHCP server IP address.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Select the configuration entries you want to remove and click Delete to remove them.

Cancel Click Cancel to clear the check boxes.

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Figure 265 IP Application > DHCP > DHCPv4 > VLAN > Port

The following table describes the labels in this screen.

41.4.8 Example: DHCP Relay for Two VLANs

The following example displays two VLANs (VIDs 1 and 2) for a campus network. Two DHCP servers are

installed to serve each VLAN. The system is set up to forward DHCP requests from the dormitory rooms

(VLAN 1) to the DHCP server with an IP address of 192.168.1.100. Requests from the academic buildings

(VLAN 2) are sent to the other DHCP server with an IP address of 172.16.10.100.

Table 182 IP Application > DHCP > DHCPv4 > VLAN > Port

LABEL DESCRIPTION

VID Enter the ID number of the VLAN you want to configure here.

Port Enter the number of port(s) to which you want to apply the specified DHCP option 82 profile.

You can enter multiple ports separated by (no space) comma (,) or hyphen (-). For example,

enter “3-5” for ports 3, 4, and 5. Enter “3,5,7” for ports 3, 5, and 7.

Option 82 Profile Select a pre-defined DHCP option 82 profile that the Switch applies to the specified port(s) in this

VLAN. The Switch adds the Circuit ID sub-option and/or Remote ID sub-option specified in the

profile to DHCP requests that it relays to a DHCP server.

The profile you select here has priority over the one you select in the DHCP > DHCPv4 > VLAN

screen.

Add Click this to create a new entry or to update an existing one.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your changes

to the non-volatile memory when you are done configuring.

Cancel Click this to reset the values above based on the last selected entry or, if not applicable, to

clear the fields above.

Clear Click Clear to reset the fields to the factory defaults.

Index This field displays a sequential number for each entry. Click an index number to change the

settings.

VID This field displays the VLAN to which the port(s) belongs.

Port This field displays the port(s) to which the Switch applies the settings.

Profile Name This field displays the DHCP option 82 profile that the Switch applies to the port(s) in this VLAN.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Select the entry(ies) that you want to remove, then click the Delete button to remove the

selected entry(ies) from the table.

Cancel Click this to clear the check boxes above.

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Figure 266 DHCP Relay for Two VLANs

For the example network, configure the VLAN Setting screen as shown.

Figure 267 DHCP Relay for Two VLANs Configuration Example

41.5 DHCPv6 Relay

A DHCPv6 relay agent is on the same network as the DHCPv6 clients and helps forward messages

between the DHCPv6 server and clients. When a client cannot use its link-local address and a well-

known multicast address to locate a DHCPv6 server on its network, it then needs a DHCPv6 relay agent

to send a message to a DHCPv6 server that is not attached to the same network.

The DHCPv6 relay agent can add the remote identification (remote-ID) option and the interface-ID

option to the Relay-Forward DHCPv6 messages. The remote-ID option carries a user-defined string, such

as the system name. The interface-ID option provides slot number, port information and the VLAN ID to

the DHCPv6 server. The remote-ID option (if any) is stripped from the Relay-Reply messages before the

relay agent sends the packets to the clients. The DHCPv6 server copies the interface-ID option from the

Relay-Forward message into the Relay-Reply message and sends it to the relay agent. The interface-ID

should not change even after the relay agent restarts.

Use this screen to configure DHCPv6 relay settings for a specific VLAN on the Switch. Click IP Application

> DHCP > DHCPv6 in the navigation panel to display the screen as shown.

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Figure 268 IP Application > DHCP > DHCPv6

The following table describes the labels in this screen.

Table 183 IP Application > DHCP > DHCPv6

LABEL DESCRIPTION

VID Enter the ID number of the VLAN you want to configure here.

Helper Address Enter the remote DHCPv6 server address for the specified VLAN.

Options

Interface ID Select this option to have the Switch add the interface-ID option in the DHCPv6 requests from

the clients in the specified VLAN before the Switch forwards them to a DHCPv6 server.

Remote ID Enter a string of up to 64 printable characters to be carried in the remote-ID option. The Switch

adds the remote-ID option in the DHCPv6 requests from the clients in the specified VLAN before

the Switch forwards them to a DHCPv6 server.

Add Click this to create a new entry or to update an existing one.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your changes

to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to their last saved values.

Clear Click Clear to reset the fields to the factory defaults.

VID This field displays the VLAN ID number. Click the VLAN ID to change the settings.

Helper Address This field displays the IPv6 address of the remote DHCPv6 server for this VLAN.

Interface ID This field displays whether the interface-ID option is added to DHCPv6 requests from clients in this

VLAN.

Remote ID This field displays whether the remote-ID option is added to DHCPv6 requests from clients in this

VLAN.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Check the entry(ies) that you want to remove and then click the Delete button.

Cancel Click Cancel to clear the selected check boxes.

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CHAPTER 42

ARP Setup

42.1 ARP Overview

Address Resolution Protocol (ARP) is a protocol for mapping an Internet Protocol address (IP address) to

a physical machine address, also known as a Media Access Control or MAC address, on the local area

network.

An IP (version 4) address is 32 bits long. In an Ethernet LAN, MAC addresses are 48 bits long. The ARP

table maintains an association between each MAC address and its corresponding IP address.

42.1.1 What You Can Do

• Use the ARP Learning screen (Section 42.2.1 on page 356) to configure ARP learning mode on a per-

port basis.

42.1.2 What You Need to Know

Read on for concepts on ARP that can help you configure the screen in this chapter.

42.1.2.1 How ARP Works

When an incoming packet destined for a host device on a local area network arrives at the Switch, the

Switch looks in the ARP Table and if it finds the address, it sends it to the device.

If no entry is found for the IP address, ARP broadcasts the request to all the devices on the LAN. The

Switch fills in its own MAC and IP address in the sender address fields, and puts the known IP address of

the target in the target IP address field. In addition, the Switch puts all ones in the target MAC field

(FF.FF.FF.FF.FF.FF is the Ethernet broadcast address). The replying device (which is either the IP address of

the device being sought or the router that knows the way) replaces the broadcast address with the

target's MAC address, swaps the sender and target pairs, and unicasts the answer directly back to the

requesting machine. ARP updates the ARP Table for future reference and then sends the packet to the

MAC address that replied.

42.1.2.2 ARP Learning Mode

The Switch supports three ARP learning modes: ARP-Reply, Gratuitous-ARP, and ARP-Request.

ARP-Reply

The Switch in ARP-Reply learning mode updates the ARP table only with the ARP replies to the ARP

requests sent by the Switch. This can help prevent ARP spoofing.

In the following example, the Switch does not have IP address and MAC address mapping information

for hosts A and B in its ARP table, and host A wants to ping host B. Host A sends an ARP request to the

Switch and then sends an ICMP request after getting the ARP reply from the Switch. The Switch finds no

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matched entry for host B in the ARP table and broadcasts the ARP request to all the devices on the LAN.

When the Switch receives the ARP reply from host B, it updates its ARP table and also forwards host A’s

ICMP request to host B. After the Switch gets the ICMP reply from host B, it sends out an ARP request to

get host A’s MAC address and updates the ARP table with host A’s ARP reply. The Switch then can

forward host B’s ICMP reply to host A.

Gratuitous-ARP

A gratuitous ARP is an ARP request in which both the source and destination IP address fields are set to

the IP address of the device that sends this request and the destination MAC address field is set to the

broadcast address. There will be no reply to a gratuitous ARP request.

A device may send a gratuitous ARP packet to detect IP collisions. If a device restarts or its MAC address

is changed, it can also use gratuitous ARP to inform other devices in the same network to update their

ARP table with the new mapping information.

In Gratuitous-ARP learning mode, the Switch updates its ARP table with either an ARP reply or a

gratuitous ARP request.

ARP-Request

When the Switch is in ARP-Request learning mode, it updates the ARP table with both ARP replies,

gratuitous ARP requests and ARP requests.

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Therefore in the following example, the Switch can learn host A’s MAC address from the ARP request

sent by host A. The Switch then forwards host B’s ICMP reply to host A right after getting host B’s MAC

address and ICMP reply.

42.2 ARP Setup

Click IP Application > ARP Setup in the navigation panel to display the screen as shown. Click the link

next to ARP Learning to open a screen where you can set the ARP learning mode for each port.

Figure 269 IP Application > ARP Setup

42.2.1 ARP Learning

Use this screen to configure each port’s ARP learning mode. Click the link next to ARP Learning in the IP

Application > ARP Setup screen to display the screen as shown next.

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Figure 270 IP Application > ARP Setup > ARP Learning

The following table describes the labels in this screen.

Table 184 IP Application > ARP Setup > ARP Learning

LABEL DESCRIPTION

Port This field displays the port number.

* Settings in this row apply to all ports.

Use this row only if you want to make some settings the same for all ports. Use this row first to set

the common settings and then make adjustments on a port-by-port basis.

Changes in this row are copied to all the ports as soon as you make them.

ARP Learning

Mode

Select the ARP learning mode the Switch uses on the port.

Select ARP-Reply to have the Switch update the ARP table only with the ARP replies to the ARP

requests sent by the Switch.

Select Gratuitous-ARP to have the Switch update its ARP table with either an ARP reply or a

gratuitous ARP request.

Select ARP-Request to have the Switch update the ARP table with both ARP replies, gratuitous

ARP requests and ARP requests.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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CHAPTER 43

Maintenance

43.1 Overview

This chapter explains how to configure the screens that let you maintain the firmware and configuration

files.

43.1.1 What You Can Do

• Use the Maintenance screen (Section 43.2 on page 358) to erase running configuration, save a

configuration file or restart the Switch.

• Use the Firmware Upgrade screen (Section 43.6 on page 362) to upload the latest firmware.

• Use the Restore Configuration screen (Section 43.7 on page 364) to upload a stored device

configuration file.

• Use the Backup Configuration screen (Section 43.8 on page 364) to save your configurations for later

use.

• Use the Auto Configuration screen (Section 43.9 on page 365) to overwrite the running configuration

stored in the Switch’s RAM.

• Use the Erase Running-Configuration screen (Section 43.3 on page 360) to reset the configuration to

the Zyxel default configuration settings.

• Use the Save Configuration screen (Section 43.4 on page 360) to save the current configuration

settings to a specific configuration file on the Switch.

• Use the Reboot System screen (Section 43.5 on page 361) to restart the Switch without physically

turning the power off and load a specific configuration file.

• Use the Tech-Support screen (Section 43.10 on page 366) to create reports for customer support if

there are problems with the Switch.

• Use the Certificates screen (Section 43.11 on page 368) to import the Switch's CA-signed certificates.

43.2 The Maintenance Screen

Use this screen to manage firmware and your configuration files. Click Management > Maintenance in

the navigation panel to open the following screen.

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Figure 271 Management > Maintenance

The following table describes the labels in this screen.

Table 185 Management > Maintenance

LABEL DESCRIPTION

Firmware

Upgrade

Click Click Here to go to the Firmware Upgrade screen.

Restore

Configuration

Click Click Here to go to the Restore Configuration screen.

Backup

Configuration

Click Click Here to go to the Backup Configuration screen.

Auto

Configuration

Click Click Here to go to the Auto Configuration screen.

Erase Running-

Configuration

Click Click Here to reset the current configuration of the Switch. Note that this will not reset the

configuration to the factory default settings.

Save

Configuration

Click Config 1 to save the current configuration settings to Configuration 1 on the Switch.

Click Config 2 to save the current configuration settings to Configuration 2 on the Switch.

Click Custom Default to save the current configuration settings to a custom default file on the

Switch.

Reboot System Click Config 1 to reboot the system and load Configuration 1 on the Switch.

Click Config 2 to reboot the system and load Configuration 2 on the Switch.

Click Factory Default to reboot the system and load the default configuration settings on the

Switch.

Click Custom Default to reboot the system and load a saved custom default file on the Switch.

This will save the custom default configuration settings to both Configuration 1 and

Configuration 2. If a custom default file was not saved, clicking Custom Default loads the

factory default configuration on the Switch.

Note: Make sure to click the Save button in any screen to save your settings to the

current configuration on the Switch.

Current This field displays which configuration (Configuration 1 or Configuration 2) is currently operating

on the Switch.

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43.3 Erase Running-Configuration

Follow the steps below to clear current configuration on the Switch. Note that this will NOT reset the

Switch back to its factory defaults. If you want to change the Switch to its factory default mode, click

the Factory Default button in Reboot System.

1In the Maintenance screen, click the Click Here button next to Erase Running-Configuration to clear all

Switch configuration information you configured you configured on the Switch.

2 Click OK to remove the running configuration on the Switch.

Figure 272 Erase Running-Configuration: Confirmation

3In the web configurator, click the Save button in the top of the screen to make the changes take effect.

If you want to access the Switch web configurator again, you may need to change the IP address of

your computer to be in the same subnet as that of the default Switch IP address (192.168.1.1 or DHCP-

assigned IP).

43.4 Save Configuration

Click Config 1 to save the current configuration settings permanently to configuration one on the

Switch.

Click Config 2 to save the current configuration settings permanently to configuration two on the Switch.

Click Custom Default to save the current configuration settings permanently to a custom default file on

the Switch. If configuration changes cause the Switch to behave abnormally, click Custom Default (next

to Reboot System) to have the Switch automatically reboot and restore the saved Custom Default

configuration file.

Alternatively, click Save on the top right-hand corner in any screen to save the configuration changes

to the current configuration.

Note: Clicking the Apply or Add button does NOT save the changes permanently. All

unsaved changes are erased after you reboot the Switch.

Tech-Support Click Click Here to see the Tech-Support screen. You can set CPU and memory thresholds for

log reports and download related log reports for issue analysis. Log reports include CPU history

and utilization, crash and memory.

Certificates Click Click Here to see the Certificates screen and import the Switch's CA-signed certificates.

Table 185 Management > Maintenance (continued)

LABEL DESCRIPTION

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43.5 Reboot System

Reboot System allows you to restart the Switch without physically turning the power off. It also allows you

to load configuration one (Config 1), configuration two (Config 2), a Custom Default or Factory Default

when you reboot. Follow the steps below to reboot the Switch.

1In the Maintenance screen, click a configuration button next to Reboot System to reboot and load that

configuration file. The following screen displays.

Figure 273 Reboot System: Confirmation

2Click OK again and then wait for the Switch to restart. This takes up to two minutes. This does not affect

the Switch’s configuration.

Click Config 1 and follow steps 1 to 2 to reboot and load configuration one on the Switch.

Click Config 2 and follow steps 1 to 2 to reboot and load configuration two on the Switch.

Click Factory Default and follow steps 1 to 2 to reboot and load default configuration settings on the

Switch.

Click Custom Default and follow steps 1 to 2 to reboot and load Custom Default configuration settings on

the Switch. This will save the custom default configuration settings to both Configuration 1 and

Configuration 2.

Note: If a customized default file was not saved, clicking Custom Default loads the factory

default configuration on the Switch.

43.5.1 Factory Default

Follow the steps below to reset the Switch back to the factory defaults.

1Click the Factory Default button.

2Click OK to continue or Cancel to abort.

Figure 274 Load Factory Default: Confirmation

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If you want to access the Switch web configurator again, you may need to change the IP address of

your computer to be in the same subnet as that of the default Switch IP address (192.168.1.1 or DHCP-

assigned IP).

43.5.2 Custom Default

Follow the steps below to reset the Switch back to the Custom Default configuration file you created.

This will save the custom default configuration settings to both Configuration 1 and Configuration 2.

1Click the Custom Default button.

2Click OK to continue or Cancel to abort.

Note: If you did not save a custom default file in the web configurator, then the factory

default file is restored after you press click Custom Default (next to Reboot System) on

the Switch. You will then have to make all your configurations again on the Switch.

Figure 275 Load Custom Default: Confirmation

43.6 Firmware Upgrade

The Switch supports dual firmware images, Firmware 1 and Firmware 2. Use this screen to specify which

image is updated when firmware is uploaded using the web configurator and to specify which image is

loaded when the Switch starts up.

Make sure you have downloaded (and unzipped) the correct model firmware and version to your

computer before uploading to the device.

Be sure to upload the correct model firmware as uploading the wrong

model firmware may damage your device.

Click Management > Maintenance > Firmware Upgrade to view the screen as shown next.

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Figure 276 Management > Maintenance > Firmware Upgrade

The top of firmware upgrade screen shows which firmware version is currently running on the Switch.

Type the path and file name of the firmware file you wish to upload to the Switch in the File Path text box

or click Choose File or Browse to locate it (Firmware upgrades are only applied after a reboot). Click

Upgrade to load the new firmware.

After the firmware upgrade process is complete, see the System Info screen to verify your current

firmware version number.

Table 186 Management > Maintenance > Firmware Upgrade

LABEL DESCRIPTION

Name This is the name of the Switch that you’re configuring.

Version The Switch has two firmware sets, Firmware 1 and Firmware 2, residing in flash.

•Running shows the version number (and model code) and MM/DD/YYYY creation date

of the firmware currently in use on the Switch (Firmware 1 or Firmware 2). The firmware

information is also displayed at System Information in Basic Settings.

•Firmware 1 shows its version number (and model code) and MM/DD/YYYY creation

date.

•Firmware 2 shows its version number (and model code) and MM/DD/YYYY creation

date.

Current Boot Image This displays which firmware is currently in use on the Switch (Firmware 1 or Firmware 2).

Config Boot Image Select which firmware (Firmware 1 or Firmware 2) should load, click Apply and reboot the

Switch to see changes, you will also see changes in the Current Boot Image field above as

well.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Firmware Choose to upload the new firmware to (Firmware) 1 or (Firmware) 2.

File Path Type the path and file name of the firmware file you wish to upload to the Switch in the File

Path text box or click Choose File or Browse to locate it.

Upgrade Click Upgrade to load the new firmware. Firmware upgrades are only applied after a

reboot. To reboot, go to Management > Maintenance > Reboot System and click Config 1,

Config 2 or Factory Default (Config 1, Config 2 and Factory Default are the configuration

files you want the Switch to use when it restarts).

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43.7 Restore Configuration

Use this screen to restore a previously saved configuration from your computer to the Switch.

Figure 277 Management > Maintenance > Restore Configuration

Type the path and file name of the configuration file you wish to restore in the File Path text box or click

Choose File or Browse to locate it. After you have specified the file, click Restore. "config" is the name of

the configuration file on the Switch, so your backup configuration file is automatically renamed when

you restore using this screen.

43.8 Backup Configuration

Backing up your Switch configurations allows you to create various “snap shots” of your device from

which you may restore at a later date.

Back up your current Switch configuration to a computer using the Backup Configuration screen.

Figure 278 Management > Maintenance > Backup Configuration

Follow the steps below to back up the current Switch configuration to your computer in this screen.

1Select which Switch configuration file you want to download to your computer.

2Click Backup.

3If the current configuration file is open and/or downloaded to your computer automatically, you can

click File > Save As to save the file to a specific place.

If a dialog box pops up asking whether you want to open or save the file, click Save or Save File to

download it to the default downloads folder on your computer. If a Save As screen displays after you

click Save or Save Fil e, choose a location to save the file on your computer from the Save in drop-down

list box and type a descriptive name for it in the File name list box. Click Save to save the configuration

file to your computer.

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43.9 Auto Configuration

The Switch can download an pre-saved auto configuration file automatically when you reboot the

Switch using the DHCP or HTTPS mode. This will overwrite the running configuration stored in the Switch’s

RAM instead of the startup configuration stored in the Switch’s flash memory.

Figure 279 Management > Maintenance > Auto Configuration

The following table describes the labels in this screen.

Table 187 Management > Maintenance > Auto Configuration

LABEL DESCRIPTION

Use this section to view the auto configuration status after you restarted the Switch.

Mode This field shows the mode (DHCP or HTTPS) that is used for auto configuration after you enabled

auto configuration and restarted the Switch.

It shows None if auto configuration was not enabled.

State This field shows whether auto configuration was executed successfully the last time the Switch

rebooted.

None - Auto configuration was disabled and not executed.

Success - An auto configuration file was downloaded successfully to the Switch.

Un-success - An auto configuration file was not downloaded to the Switch.

Filename This field displays the name of the auto configuration file that was downloaded the last time the

Switch rebooted.

It shows None if auto configuration was not enabled or not executed successfully.

Use this section to enable auto configuration and select the mode that you want to use for auto configuration.

Active Select the check box to enable auto configuration.

Mode Select DHCP to have the Switch use the TFTP server IP address and auto configuration file name

assigned by a DHCP server to download a pre-saved configuration file when the Switch

reboots.

Note: The Switch should act as a DHCP client to send a DHCP request so that it can

get the TFTP server address and configuration file name from the DHCP server.

See Section 6.4 on page 70 for more information about how to use auto

configuration.

Select HTTPS to have the Switch use the URL you specified in the HTTPS URL field to access a web

server and download the auto configuration file using HTTPS.

DHCP VLAN ID Enter the VLAN ID of the DHCP server that assigns the TFTP server IP address and auto

configuration file name to the Switch.

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43.10 Tech-Support

The Tech-Support feature is a log enhancement tool that logs useful information such as CPU utilization

history, memory and Mbuf (Memory Buffer) log and crash reports for issue analysis by customer support

should you have difficulty with your Switch. The Tech Support menu eases your effort in obtaining reports.

Click Management > Maintenance > Tech-Support to see the following screen.

Figure 280 Management > Maintenance > Tech-Support

HTTPS URL Type the URL that can be used to access and download the auto configuration file from a web

server using HTTPS. For example, https://webserverIPaddress/configfilename.cfg.

Note: You must fill in this field if you select HTTPS in the Mode field. Otherwise, auto

configuration won’t work.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 187 Management > Maintenance > Auto Configuration

LABEL DESCRIPTION

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You may need WordPad or similar software to see the log report correctly. The table below describes

the fields in the above screen.

43.10.1 Tech-Support Download

When you click Download to save your current Switch configuration to a computer, the following screen

appears. When the log report has downloaded successfully, click Back to return to the previous screen.

Figure 281 Management > Maintenance > Tech-Support: Download

Table 188 Management > Maintenance > Tech-Support

LABEL DESCRIPTION

CPU Type a number ranging from 50 to 100 in the CPU threshold box, and type another

number ranging from 5 to 60 in the seconds box then click Apply.

For example, 80 for CPU threshold and 5 for seconds means a log will be created when

CPU utilization reaches over 80% and lasts for 5 seconds.

The log report holds 7 days of CPU log data and is stored in volatile memory (RAM). The

data is lost if the Switch is turned off or in event of power outage. After 7 days, the logs

wrap around and new ones and replace the earliest ones.

The higher the CPU threshold number, the fewer logs will be created, and the less data

technical support will have to analyze and vice versa.

Mbuf Type a number ranging from 50 to 100 in the Mbuf (Memory Buffer) threshold box. The

Mbuf log report is stored in flash (permanent) memory.

For example, Mbuf 50 means a log will be created when the Mbuf utilization is over 50%.

The higher the Mbuf threshold number, the fewer logs will be created, and the less data

technical support will have to analyze and vice versa.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses

these changes if it is turned off or loses power, so use the Save link on the top navigation

panel to save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

All Click Download to see all the log report and system status. This log report is stored in flash

memory. If the All log report is too large, you can download the log reports separately

below.

Crash Click Download to see the crash log report. The log will include information of the last

crash and is stored in flash memory.

CPU history Click Download to see the CPU history log report. The 7-days log is stored in RAM and you

will need to save it, otherwise it will be lost when the Switch is shutdown or during power

outage.

Memory Section Click Download to see the memory section log report. This log report is stored in flash

memory.

Mbuf Click Download to see the Mbuf log report. The log includes Mbuf over threshold

information. This log report is stored in flash memory.

ROM Click Download to see the Read Only Memory (ROM) log report. This report is stored in

flash memory.

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43.11 Certificates

The Switch can use HTTPS certificates that are verified by a third party to create secure HTTPS

connections between your computer and the Switch. This way, you may securely access the Switch

using the web configurator. See Section 44.7.3 on page 386 for more information about HTTPS.

Certificates are based on public-private key pairs. A certificate contains the certificate owner’s identity

and public key. Certificates provide a way to exchange public keys for use in authentication.

Click Management > Maintenance > Certificates to open the following screen. Use this screen to import

the Switch's CA-signed certificates.

Figure 282 Management > Maintenance > Certificates

The following table describes the labels in this screen.

Table 189 Management > Maintenance > Certificates

LABEL DESCRIPTION

File Path Click Choose File or Browse to find the certificate file you want to upload.

Password Type the certificate file’s password that was created when the PKCS #12 file was exported. The

password consists of up to 32 ASCII characters.

Import Click this button to save the certificate that you have enrolled from a certification authority

from your computer to the Switch.

Service This field displays the service type that this certificate is for.

Subject This field displays identifying information about the certificate’s owner, such as CN (Common

Name), OU (Organizational Unit or department), O (Organization or company) and C

(Country). It is recommended that each certificate have unique subject information.

Issuer This field displays identifying information about the certificate’s issuing certification authority,

such as a common name, organizational unit or department, organization or company and

country.

Valid From This field displays the date that the certificate becomes applicable.

Valid To This field displays the date that the certificate expires.

Select an entry’s check box to select a specific entry.

Delete Click this button to delete the certificate (or certification request). You cannot delete a

certificate that one or more features is configured to use.

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43.11.1 HTTPS Certificates

Use this screen to view the HTTPS certificate details. Click a hyperlink in the Service column in the

Management > Maintenance > Certificates screen to open the following screen.

Figure 283 Management > Maintenance > Certificates > HTTPS

43.12 Technical Reference

This section provides technical background information on the topics discussed in this chapter.

43.12.1 FTP Command Line

This section shows some examples of uploading to or downloading files from the Switch using FTP

commands. First, understand the filename conventions.

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43.12.2 Filename Conventions

The configuration file (also known as the romfile or ROM) contains the factory default settings in the

screens such as password, Switch setup, IP Setup, and so on. Once you have custom the Switch’s

settings, they can be saved back to your computer under a filename of your choosing.

ZyNOS (Zyxel Network Operating System sometimes referred to as the “ras” file) is the system firmware

and has a “bin” filename extension.

43.12.2.1 Example FTP Commands

ftp> put firmware.bin ras

This is a sample FTP session showing the transfer of the computer file "firmware.bin" to the Switch.

ftp> get config config.cfg

This is a sample FTP session saving the current configuration to a file called “config.cfg” on your

computer.

If your (T)FTP client does not allow you to have a destination filename different than the source, you will

need to rename them as the Switch only recognizes “config” and “ras”. Be sure you keep unaltered

copies of both files for later use.

Be sure to upload the correct model firmware as uploading the wrong

model firmware may damage your device.

43.12.3 FTP Command Line Procedure

1Launch the FTP client on your computer.

2Enter open, followed by a space and the IP address of your Switch.

3Press [ENTER] when prompted for a username.

4Enter your password as requested (the default is “1234”).

5Enter bin to set transfer mode to binary.

Table 190 Filename Conventions

FILE TYPE INTERNAL NAME EXTERNAL NAME DESCRIPTION

Configuration File config *.cfg This is the configuration filename on the

Switch. Uploading the config file replaces

the specified configuration file system,

including your Switch configurations,

system-related data (including the default

password), the error log and the trace log.

Firmware ras *.bin This is the generic name for the ZyNOS

firmware on the Switch.

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6Use put to transfer files from the computer to the Switch, for example, put firmware.bin ras transfers

the firmware on your computer (firmware.bin) to the Switch and renames it to “ras”. Similarly, put

config.cfg config transfers the configuration file on your computer (config.cfg) to the Switch and

renames it to “config”. Likewise get config config.cfg transfers the configuration file on the Switch

to your computer and renames it to “config.cfg”. See Table 190 on page 370 for more information on

filename conventions.

7Enter quit to exit the ftp prompt.

43.12.4 GUI-based FTP Clients

The following table describes some of the commands that you may see in GUI-based FTP clients.

43.12.5 FTP Restrictions

FTP will not work when:

• FTP service is disabled in the Service Access Control screen.

• The IP address(es) in the Remote Management screen does not match the client IP address. If it does

not match, the Switch will disconnect the FTP session immediately.

General Commands for GUI-based FTP Clients

COMMAND DESCRIPTION

Host Address Enter the address of the host server.

This is when a user I.D. and password is automatically supplied to the server for

anonymous access. Anonymous logins will work only if your ISP or service administrator

has enabled this option.

Normal.

The server requires a unique User ID and Password to login.

Transfer Type Transfer files in either ASCII (plain text format) or in binary mode. Configuration and

firmware files should be transferred in binary mode.

Initial Remote Directory Specify the default remote directory (path).

Initial Local Directory Specify the default local directory (path).

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CHAPTER 44

Access Control

44.1 Access Control Overview

This chapter describes how to control access to the Switch.

A console port and FTP are allowed one session each. Telnet and SSH share nine sessions. Up to five Web

sessions (five different user names and passwords) and/or limitless SNMP access control sessions are

allowed.

A console port access control session and Telnet access control session cannot coexist when multi-login

is disabled. See the CLI Reference Guide for more information on disabling multi-login.

44.1.1 What You Can Do

• Use the Access Control screen (Section 44.2 on page 372) to display the main screen.

• Use the SNMP screen (Section 44.3 on page 373) to configure your SNMP settings.

• Use the Trap Group screen (Section 44.3.1 on page 374) to specify the types of SNMP traps that should

be sent to each SNMP manager.

• Use the User Information screen (Section 44.3.3 on page 376) to create SNMP users for authentication

with managers using SNMP v3 and associate them to SNMP groups.

• Use the Logins screens (Section 44.4 on page 378) to assign which users can access the Switch via

web configurator at any one time.

• Use the Service Access Control screen (Section 44.5 on page 380) to decide what services you may

use to access the Switch.

• Use the Remote Management screen (Section 44.6 on page 380) to specify a group of one or more

“trusted computers” from which an administrator may use a service to manage the Switch.

44.2 The Access Control Main Screen

Use this screen to display the main screen.Click Management > Access Control in the navigation panel

to display the main screen as shown.

Table 191 Access Control Overview

Console Port SSH Telnet FTP Web SNMP

One session Share up to nine sessions One session Up to five accounts No limit

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Figure 284 Management > Access Control

The following table describes the labels in this screen.

44.3 Configuring SNMP

Use this screen to configure your SNMP settings.

Click Management > Access Control > SNMP to view the screen as shown.

Figure 285 Management > Access Control > SNMP

Table 192 Management > Access Control

LABEL DESCRIPTION

SNMP Click this link to configure your SNMP settings.

Logins Click this link to assign which users can access the Switch via web configurator at any one

time.

Service Access

Control

Click this link to decide what services you may use to access the Switch.

Remote

Management

Click this link to specify a group of one or more “trusted computers” from which an

administrator may use a service to manage the Switch.

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The following table describes the labels in this screen.

44.3.1 Configuring SNMP Trap Group

From the SNMP screen, click Trap Group to view the screen as shown. Use the Trap Group screen to

specify the types of SNMP traps that should be sent to each SNMP manager.

Table 193 Management > Access Control > SNMP

LABEL DESCRIPTION

General Setting Use this section to specify the SNMP version and community (password) values.

Version Select the SNMP version for the Switch. The SNMP version on the Switch must match the

version on the SNMP manager. Choose SNMP version 2c (v2c), SNMP version 3 (v3) or both

(v3v2c).

SNMP version 2c is backwards compatible with SNMP version 1.

Get Community Enter the Get Community string, which is the password for the incoming Get- and GetNext-

requests from the management station.

The Get Community string is only used by SNMP managers using SNMP version 2c or lower.

Set Community Enter the Set Community, which is the password for incoming Set- requests from the

management station.

The Set Community string is only used by SNMP managers using SNMP version 2c or lower.

Trap Community Enter the Trap Community string, which is the password sent with each trap to the SNMP

manager.

The Trap Community string is only used by SNMP managers using SNMP version 2c or lower.

Trap Destination Use this section to configure where to send SNMP traps from the Switch.

Version Specify the version of the SNMP trap messages.

IP Enter the IP addresses of up to four managers to send your SNMP traps to.

Port Enter the port number upon which the manager listens for SNMP traps.

Username Enter the username to be sent to the SNMP manager along with the SNMP v3 trap.

This username must match an existing account on the Switch (configured in Management >

Access Control > Logins screen).

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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Figure 286 Management > Access Control > SNMP > Trap Group

The following table describes the labels in this screen.

44.3.2 Enabling/Disabling Sending of SNMP Traps on a Port

From the SNMP > Trap Group screen, click Port to view the screen as shown. Use this screen to set

whether a trap received on the port(s) would be sent to the SNMP manager.

Table 194 Management > Access Control > SNMP > Trap Group

LABEL DESCRIPTION

Trap Destination IP Select one of your configured trap destination IP addresses. These are the IP addresses of the

SNMP managers. You must first configure a trap destination IP address in the SNMP Setting

screen.

Use the rest of the screen to select which traps the Switch sends to that SNMP manager.

Type Select the categories of SNMP traps that the Switch is to send to the SNMP manager.

Options Select the individual SNMP traps that the Switch is to send to the SNMP station. See SNMP Traps

on page 383 for individual trap descriptions.

The traps are grouped by category. Selecting a category automatically selects all of the

category’s traps. Clear the check boxes for individual traps that you do not want the Switch

to send to the SNMP station. Clearing a category’s check box automatically clears all of the

category’s trap check boxes (the Switch only sends traps from selected categories).

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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Figure 287 Management > Access Control > SNMP > Trap Group > Port

The following table describes the labels in this screen.

44.3.3 Configuring SNMP User

From the SNMP screen, click User to view the screen as shown. Use the User screen to create SNMP users

for authentication with managers using SNMP v3 and associate them to SNMP groups. An SNMP user is

an SNMP manager.

Table 195 Management > Access Control > SNMP > Trap Group > Port

LABEL DESCRIPTION

Option Select the trap type you want to configure here.

Port This field displays a port number.

* Settings in this row apply to all ports.

Use this row only if you want to make some of the settings the same for all ports. Use this row

first to set the common settings and then make adjustments on a port-by-port basis.

Changes in this row are copied to all the ports as soon as you make them.

Active Select this check box to enable the trap type of SNMP traps on this port.

Clear this check box to disable the sending of SNMP traps on this port.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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Figure 288 Management > Access Control > SNMP > User

The following table describes the labels in this screen.

Table 196 Management > Access Control > SNMP > User

LABEL DESCRIPTION

User Information Note: Use the username and password of the login accounts you specify in this

screen to create accounts on the SNMP v3 manager.

Username Specify the username of a login account on the Switch.

Security Level Select whether you want to implement authentication and/or encryption for SNMP

communication from this user. Choose:

•noauth -to use the username as the password string to send to the SNMP manager. This is

equivalent to the Get, Set and Trap Community in SNMP v2c. This is the lowest security

level.

•auth - to implement an authentication algorithm for SNMP messages sent by this user.

•priv - to implement authentication and encryption for SNMP messages sent by this user.

This is the highest security level.

Note: The settings on the SNMP manager must be set at the same security level or

higher than the security level settings on the Switch.

Authentication Select an authentication algorithm. MD5 (Message Digest 5) and SHA (Secure Hash Algorithm)

are hash algorithms used to authenticate SNMP data. SHA authentication is generally

considered stronger than MD5, but is slower.

Password Enter the password of up to 32 ASCII characters for SNMP user authentication.

Privacy Specify the encryption method for SNMP communication from this user. You can choose one

of the following:

•DES - Data Encryption Standard is a widely used (but breakable) method of data

encryption. It applies a 56-bit key to each 64-bit block of data.

•AES - Advanced Encryption Standard is another method for data encryption that also uses

a secret key. AES applies a 128-bit key to 128-bit blocks of data.

Password Enter the password of up to 32 ASCII characters for encrypting SNMP packets.

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44.4 Logins

Up to five people (one administrator and four non-administrators) may access the Switch via web

configurator at any one time.

• An administrator is someone who can both view and configure Switch changes. The username for the

Administrator is always admin. The default administrator password is 1234.

Note: It is highly recommended that you change the default administrator password (1234).

• A non-administrator (username is something other than admin) is someone who can view and/or

configure Switch settings. The configuration right varies depending on the user’s privilege level.

Click Management > Access Control > Logins to view the screen as shown.

Group SNMP v3 adopts the concept of View-based Access Control Model (VACM) group. SNMP

managers in one group are assigned common access rights to MIBs. Specify in which SNMP

group this user is.

admin - Members of this group can perform all types of system configuration, including the

management of administrator accounts.

readwrite - Members of this group have read and write rights, meaning that the user can

create and edit the MIBs on the Switch, except the user account and AAA configuration.

readonly - Members of this group have read rights only, meaning the user can collect

information from the Switch.

Add Click this to create a new entry or to update an existing one.

This saves your changes to the Switch’s run-time memory. The Switch loses these changes if it is

turned off or loses power, so use the Save link on the top navigation panel to save your

changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to reset the fields to your previous configuration.

Clear Click Clear to reset the fields to the factory defaults.

Index This is a read-only number identifying a login account on the Switch. Click on an index number

to view more details and edit an existing account.

Username This field displays the username of a login account on the Switch.

Security Level This field displays whether you want to implement authentication and/or encryption for SNMP

communication with this user.

Authentication This field displays the authentication algorithm used for SNMP communication with this user.

Privacy This field displays the encryption method used for SNMP communication with this user.

Group This field displays the SNMP group to which this user belongs.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Click Delete to remove the selected entry from the summary table.

Cancel Click Cancel to begin configuring this screen afresh.

Table 196 Management > Access Control > SNMP > User (continued)

LABEL DESCRIPTION

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Figure 289 Management > Access Control > Logins

The following table describes the labels in this screen.

Table 197 Management > Access Control > Logins

LABEL DESCRIPTION

Administrator

This is the default administrator account with the “admin” user name. You cannot change the default administrator

user name.

Old Password Type the existing system password (1234 is the default password when shipped).

New Password Enter your new system password.

Retype to

confirm Retype your new system password for confirmation.

Edit Logins

You may configure passwords for up to four users. These users can have read-only or read/write access. You can

give users higher privileges via the web configurator.

User Name Set a user name (up to 32 ASCII characters long).

Password Enter your new system password.

Retype to

confirm Retype your new system password for confirmation.

Privilege Type the privilege level for this user. At the time of writing, users may have a privilege level of 0,

3, 13, or 14 representing different configuration rights as shown below.

• 0 - Display basic system information.

• 3 - Display configuration or status.

• 13 - Configure features except for login accounts, SNMP user accounts, the

authentication method sequence and authorization settings, multiple logins, administrator

and enable passwords, and configuration information display.

• 14 - Configure login accounts, SNMP user accounts, the authentication method sequence

and authorization settings, multiple logins, and administrator and enable passwords, and

display configuration information.

Users can run command lines if the session’s privilege level is greater than or equal to the

command’s privilege level. The session privilege initially comes from the privilege of the login

account. For example, if the user has a privilege of 5, he/she can run commands that requires

privilege level of 5 or less but not more.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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44.5 Service Access Control

Service Access Control allows you to decide what services you may use to access the Switch. You may

also change the default service port and configure “trusted computer(s)” for each service in the

Remote Management screen (discussed later). Click Access Control to go back to the main Access

Control screen.

Figure 290 Management > Access Control > Service Access Control

The following table describes the fields in this screen.

44.6 Remote Management

Use this screen to specify a group of one or more “trusted computers” from which an administrator may

use a service to manage the Switch.

Table 198 Management > Access Control > Service Access Control

LABEL DESCRIPTION

Services Services you may use to access the Switch are listed here.

Active Select this option for the corresponding services that you want to allow to access the Switch.

Service Port For Telnet, SSH, FTP, HTTP or HTTPS services, you may change the default service port by typing

the new port number in the Service Port field. If you change the default port number then you

will have to let people (who wish to use the service) know the new port number for that

service.

Timeout Type how many minutes (from 1 to 255) a management session can be left idle before the

session times out. After it times out you have to log in with your password again. Very long idle

timeouts may have security risks.

Note: The timeout period you specified for Telnet sessions also applies to SSH

sessions. Likewise, the HTTP and HTTPS sessions are set to use the same timeout

value.

failed attempt to log in and access the Switch.

Note: The login timeout period you specified for Telnet sessions also applies to SSH

sessions.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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Click Management > Access Control > Remote Management to view the screen as shown next.

You can specify a group of one or more “trusted computers” from which an administrator may use a

service to manage the Switch. Click Access Control to return to the Access Control screen.

Figure 291 Management > Access Control > Remote Management

The following table describes the labels in this screen.

44.7 Technical Reference

This section provides technical background information on the topics discussed in this chapter.

Table 199 Management > Access Control > Remote Management

LABEL DESCRIPTION

Entry This is the client set index number. A “client set” is a group of one or more “trusted computers”

from which an administrator may use a service to manage the Switch.

Active Select this check box to activate this secured client set. Clear the check box if you wish to

temporarily disable the set without deleting it.

Start Address

End Address

Configure the IP address range of trusted computers from which you can manage this Switch.

The Switch checks if the client IP address of a computer requesting a service or protocol matches

the range set here. The Switch immediately disconnects the session if it does not match.

Telnet/FTP/

HTTP/ICMP/

SNMP/SSH/

HTTPS

Select services that may be used for managing the Switch from the specified trusted computers.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

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44.7.1 About SNMP

Simple Network Management Protocol (SNMP) is an application layer protocol used to manage and

monitor TCP/IP-based devices. SNMP is used to exchange management information between the

network management system (NMS) and a network element (NE). A manager station can manage and

monitor the Switch through the network via SNMP version 1 (SNMPv1), SNMP version 2c or SNMP version

3. The next figure illustrates an SNMP management operation. SNMP is only available if TCP/IP is

configured.

Figure 292 SNMP Management Model

An SNMP managed network consists of two main components: agents and a manager.

An agent is a management software module that resides in a managed Switch (the Switch). An agent

translates the local management information from the managed Switch into a form compatible with

SNMP. The manager is the console through which network administrators perform network management

functions. It executes applications that control and monitor managed devices.

The managed devices contain object variables/managed objects that define each piece of

information to be collected about a Switch. Examples of variables include number of packets received,

node port status and so on. A Management Information Base (MIB) is a collection of managed objects.

SNMP allows a manager and agents to communicate for the purpose of accessing these objects.

SNMP itself is a simple request/response protocol based on the manager/agent model. The manager

issues a request and the agent returns responses using the following protocol operations:

SNMP v3 and Security

SNMP v3 enhances security for SNMP management. SNMP managers can be required to authenticate

with agents before conducting SNMP management sessions.

Table 200 SNMP Commands

LABEL DESCRIPTION

Get Allows the manager to retrieve an object variable from the agent.

GetNext Allows the manager to retrieve the next object variable from a table or list within an agent. In

SNMPv1, when a manager wants to retrieve all elements of a table from an agent, it initiates a

Get operation, followed by a series of GetNext operations.

Set Allows the manager to set values for object variables within an agent.

Trap Used by the agent to inform the manager of some events.

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Security can be further enhanced by encrypting the SNMP messages sent from the managers.

Encryption protects the contents of the SNMP messages. When the contents of the SNMP messages are

encrypted, only the intended recipients can read them.

Supported MIBs

MIBs let administrators collect statistics and monitor status and performance.

The Switch supports the following MIBs:

• SNMP MIB II (RFC 1213)

• RFC 1157 SNMP v1

• RFC 1493 Bridge MIBs

• RFC 1643 Ethernet MIBs

• RFC 1155 SMI

• RFC 2674 SNMPv2, SNMPv2c

• RFC 1757 RMON

• SNMPv2, SNMPv2c or later version, compliant with RFC 2011 SNMPv2 MIB for IP, RFC 2012 SNMPv2 MIB

for TCP, RFC 2013 SNMPv2 MIB for UDP

SNMP Traps

The Switch sends traps to an SNMP manager when an event occurs. The following tables outline the

SNMP traps by category.

Table 201 SNMP System Traps

OPTION OBJECT LABEL OBJECT ID DESCRIPTION

coldstart coldStart 1.3.6.1.6.3.1.1.5.1 This trap is sent when the Switch is turned

on.

warmstart warmStart 1.3.6.1.6.3.1.1.5.2 This trap is sent when the Switch restarts.

poe

(For PoE models

only)

pethPsePortOnOffNotificatio

1.3.6.1.2.1.105.0.1 This trap is sent when the PoE port delivers

power or delivers no power to a PD.

pethMainPowerUsageOnNo

tification

1.3.6.1.2.1.105.0.2 This trap is sent when the usage power is

above the usage indication threshold.

pethMainPowerUsageOffNo

tification

1.3.6.1.2.1.105.0.3 This trap is sent when the usage power is

below the usage indication threshold.

Table 202 SNMP Interface Traps

OPTION OBJECT LABEL OBJECT ID DESCRIPTION

linkup linkUp 1.3.6.1.6.3.1.1.5.4 This trap is sent when the Ethernet link is

up.

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linkdown linkDown 1.3.6.1.6.3.1.1.5.3 This trap is sent when the Ethernet link is

down.

lldp lldpRemTablesChange 1.0.8802.1.1.2.0.0.1 The trap is sent when entries in the

remote database have any updates.

Link Layer Discovery Protocol (LLDP),

defined as IEEE 802.1ab, enables LAN

devices that support LLDP to exchange

their configured settings. This helps

eliminate configuration mismatch issues.

Table 202 SNMP Interface Traps (continued)

OPTION OBJECT LABEL OBJECT ID DESCRIPTION

Table 203 SNMP AAA Traps

OPTION OBJECT LABEL OBJECT ID DESCRIPTION

authentication authenticationFailure 1.3.6.1.6.3.1.1.5.5 This trap is sent when authentication

fails due to incorrect user name and/or

password.

Table 204 SNMP IP Traps

OPTION OBJECT LABEL OBJECT ID DESCRIPTION

ping pingProbeFailed 1.3.6.1.2.1.80.0.1 This trap is sent when a single ping probe fails.

pingTestFailed 1.3.6.1.2.1.80.0.2 This trap is sent when a ping test (consisting of a series of

ping probes) fails.

pingTestCompleted 1.3.6.1.2.1.80.0.3 This trap is sent when a ping test is completed.

traceroute traceRouteTestFailed 1.3.6.1.2.1.81.0.2 This trap is sent when a traceroute test fails.

traceRouteTestCompleted 1.3.6.1.2.1.81.0.3 This trap is sent when a traceroute test is completed.

Table 205 SNMP Switch Traps

OPTION OBJECT LABEL OBJECT ID DESCRIPTION

stp STPNewRoot 1.3.6.1.2.1.17.0.1 This trap is sent when the STP root switch changes.

STPTopologyChange 1.3.6.1.2.1.17.0.2 This trap is sent when the STP topology changes.

rmon RmonRisingAlarm 1.3.6.1.2.1.16.0.1 This trap is sent when a variable goes over the RMON

"rising" threshold.

RmonFallingAlarm 1.3.6.1.2.1.16.0.2 This trap is sent when the variable falls below the RMON

"falling" threshold.

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44.7.2 SSH Overview

Unlike Telnet or FTP, which transmit data in clear text, SSH (Secure Shell) is a secure communication

protocol that combines authentication and data encryption to provide secure encrypted

communication between two hosts over an unsecured network.

Figure 293 SSH Communication Example

44.7.2.1 How SSH works

The following table summarizes how a secure connection is established between two remote hosts.

Figure 294 How SSH Works

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1Host Identification

The SSH client sends a connection request to the SSH server. The server identifies itself with a host key. The

client encrypts a randomly generated session key with the host key and server key and sends the result

back to the server.

The client automatically saves any new server public keys. In subsequent connections, the server public

key is checked against the saved version on the client computer.

2Encryption Method

Once the identification is verified, both the client and server must agree on the type of encryption

method to use.

3Authentication and Data Transmission

After the identification is verified and data encryption activated, a secure tunnel is established between

the client and the server. The client then sends its authentication information (user name and password)

to the server to log in to the server.

44.7.2.2 SSH Implementation on the Switch

Your Switch supports SSH version 2 using RSA authentication and three encryption methods (DES, 3DES

and Blowfish). The SSH server is implemented on the Switch for remote management and file transfer on

port 22. Only one SSH connection is allowed at a time.

44.7.2.3 Requirements for Using SSH

You must install an SSH client program on a client computer (Windows or Linux operating system) that is

used to connect to the Switch over SSH.

44.7.3 Introduction to HTTPS

HTTPS (HyperText Transfer Protocol over Secure Socket Layer, or HTTP over SSL) is a web protocol that

encrypts and decrypts web pages. Secure Socket Layer (SSL) is an application-level protocol that

enables secure transactions of data by ensuring confidentiality (an unauthorized party cannot read the

transferred data), authentication (one party can identify the other party) and data integrity (you know if

data has been changed).

It relies upon certificates, public keys, and private keys.

HTTPS on the Switch is used so that you may securely access the Switch using the web configurator. The

SSL protocol specifies that the SSL server (the Switch) must always authenticate itself to the SSL client (the

computer which requests the HTTPS connection with the Switch), whereas the SSL client only should

authenticate itself when the SSL server requires it to do so. Authenticating client certificates is optional

and if selected means the SSL-client must send the Switch a certificate. You must apply for a certificate

for the browser from a Certificate Authority (CA) that is a trusted CA on the Switch.

Please refer to the following figure.

1HTTPS connection requests from an SSL-aware web browser go to port 443 (by default) on the Switch’s

WS (web server).

2HTTP connection requests from a web browser go to port 80 (by default) on the Switch’s WS (web

server).

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Figure 295 HTTPS Implementation

Note: If you disable HTTP in the Service Access Control screen, then the Switch blocks all HTTP

connection attempts.

44.7.3.1 HTTPS Example

If you haven’t changed the default HTTPS port on the Switch, then in your browser enter “https://Switch

IP Address/” as the web site address where “Switch IP Address” is the IP address or domain name of the

Switch you wish to access.

Internet Explorer Warning Messages

Internet Explorer 6

When you attempt to access the Switch HTTPS server, a Windows dialog box pops up asking if you trust

the server certificate.

You see the following Security Alert screen in Internet Explorer. Select Yes to proceed to the web

configurator login screen; if you select No, then web configurator access is blocked.

Figure 296 Security Alert Dialog Box (Internet Explorer 6)

Internet Explorer 7 later version

When you attempt to access the Switch HTTPS server, a screen with the message "There is a problem

with this website's security certificate." may display. If that is the case, click Continue to this website (not

recommended) to proceed to the web configurator login screen.

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Figure 297 Security Certificate Warning (Internet Explorer 11)

After you log in, you will see the red address bar with the message Certificate Error. Click on Certificate

Error next to the address bar and click View certificates.

Figure 298 Certificate Error (Internet Explorer 11)

Click Install Certificate... and follow the on-screen instructions to install the certificate in your browser.

EXAMPLE

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Figure 299 Certificate (Internet Explorer 11)

Mozilla Firefox Warning Messages

When you attempt to access the Switch HTTPS server, a This Conne ction is Unstructed or Your connection

is not secure screen may display. If that is the case, click I Understand the Risks or Advanced and then

the Add Exception... button.

Figure 300 Security Alert (Mozilla Firefox 53.0)

Confirm the HTTPS server URL matches. Click Confirm Security Exception to proceed to the web

configurator login screen.

EXAMPLE

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Figure 301 Security Alert (Mozilla Firefox 53.0)

44.7.4 Google Chrome Warning Messages

When you attempt to access the Switch HTTPS server, a Your connection is not private screen may

display. If that is the case, click Advanced and then Proceed to x.x.x.x (unsafe) to proceed to the web

configurator login screen.

EXAMPLE

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Figure 302 Security Alert (Google Chrome 58.0.3029.110)

44.7.4.1 The Main Screen

After you accept the certificate and enter the login username and password, the Switch main screen

appears. The lock displayed in the bottom right of the browser status bar or next to the website address

denotes a secure connection.

Figure 303 Example: Lock Denoting a Secure Connection

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CHAPTER 45

Diagnostic

45.1 Overview

This chapter explains the Diagnostic screen. You can use this screen to help you identify problems.

45.2 Diagnostic

Click Management > Diagnostic in the navigation panel to open this screen. Use this screen to ping IP

addresses, run a traceroute, perform port tests or show the Switch’s location between devices.

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The following table describes the labels in this screen.

Table 206 Management > Diagnostic

LABEL DESCRIPTION

Ping Test

IPv4 Select this option if you want to ping an IPv4 address. Select - to send ping requests to all

VLANs on the Switch.

IPv6 Select this option if you want to ping an IPv6 address. You can also select vlan and specify

the ID number of the VLAN to which the Switch is to send ping requests. Otherwise, select - to

send ping requests to all VLANs on the Switch.

IP Address/Host

Name Type the IP address or host name of a device that you want to ping in order to test a

connection.

Click Ping to have the Switch ping the IP address.

Count Enter the number of ICMP Echo Request (ping) messages the Switch continuously sends.

Trace Route Test

IPv4 Select this option if you want to trace the route packets take to a device with an IPv4

address. Select - to trace the path on any VLAN.

Note: The device to which you want to run a traceroute must belong to the VLAN

you specify here.

IPv6 Select this option if you want to trace the route packets take to a device with an IPv6

address.

IP Address/Host

Name Enter the IP address or host name of a device to which you want to perform a traceroute.

Click Trace Route to have the Switch perform the traceroute function. This determines the

path a packet takes to the specified device.

TTL Enter the Time To Live (TTL) value for the ICMP Echo Request packets. This is to set the

maximum number of the hops (routers) a packet can travel through. Each router along the

path will decrement the TTL value by one and forward the packets. When the TTL value

becomes zero and the destination is not found, the router drops the packets and informs the

sender.

Wait Time Specify how many seconds the Switch waits for a response to a probe before running

another traceroute.

Queries Specify how many times the Switch performs the traceroute function.

Ethernet Port Test Enter a port number and click Port Test to perform an internal loopback test.

Cable Diagnostics Enter an Ethernet port number and click Diagnose to perform a physical wire-pair test of the

Ethernet connections on the specified port(s). The following fields display in the Diagnostic

field when you diagnose a port.

This field is available only on the Switch that has one or more copper Ethernet ports (except

the MGMT port).

Note: The Switch measures the cable length by sending an electric signal through

the cable and reading the signal that is reflected back. To prevent possible

interference from a connected device, it's suggested that you disconnect

the other end of the Ethernet cable which is connected to the specified

port.

Port This is the number of the physical Ethernet port on the Switch.

Locator LED Enter a time interval (in minutes) and click Blink to show the actual location of the Switch

between several devices in a rack.

The default time interval is 30 minutes.

Click Stop to have the Switch terminate the blinking locater LED.

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CHAPTER 46

System Log

46.1 Overview

A log message stores the information for viewing.

46.2 System Log

Click Management > System Log in the navigation panel to open this screen. Use this screen to check

current system logs.

Note: When a log reaches the maximum number of log messages, new log messages

automatically overwrite existing log messages, starting with the oldest existing log

message first.

Figure 305 Management > System Log

The summary table shows the time the log message was recorded and the reason the log message was

generated. Click Refresh to update this screen. Click Clear to clear the whole log, regardless of what is

currently displayed on the screen. Click Download to save the log to your computer.

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CHAPTER 47

Syslog Setup

47.1 Syslog Overview

This chapter explains the syslog screens.

The syslog protocol allows devices to send event notification messages across an IP network to syslog

servers that collect the event messages. A syslog-enabled device can generate a syslog message and

send it to a syslog server.

Syslog is defined in RFC 3164. The RFC defines the packet format, content and system log related

information of syslog messages. Each syslog message has a facility and severity level. The syslog facility

identifies a file in the syslog server. Refer to the documentation of your syslog program for details. The

following table describes the syslog severity levels.

47.1.1 What You Can Do

Use the Syslog Setup screen (Section 47.2 on page 395) to configure the device’s system logging

settings and configure a list of external syslog servers.

47.2 Syslog Setup

The syslog feature sends logs to an external syslog server. Use this screen to configure the device’s

system logging settings and configure a list of external syslog servers.

Click Management > Syslog in the navigation panel to display this screen.

Table 207 Syslog Severity Levels

CODE SEVERITY

0 Emergency: The system is unusable.

1 Alert: Action must be taken immediately.

2 Critical: The system condition is critical.

3 Error: There is an error condition on the system.

4 Warning: There is a warning condition on the system.

5 Notice: There is a normal but significant condition on the system.

6 Informational: The syslog contains an informational message.

7 Debug: The message is intended for debug-level purposes.

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Figure 306 Management > Syslog Setup

The following table describes the labels in this screen.

Table 208 Management > Syslog Setup

LABEL DESCRIPTION

Syslog Select Active to turn on syslog (system logging) and then configure the syslog setting

Logging Type This column displays the names of the categories of logs that the device can generate.

Active Select this option to set the device to generate logs for the corresponding category.

Facility The log facility allows you to send logs to different files in the syslog server. Refer to the

documentation of your syslog program for more details.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Syslog Server Setup

Active Select this check box to have the device send logs to this syslog server. Clear the check box

if you want to create a syslog server entry but not have the device send logs to it (you can

edit the entry later).

Server Address Enter the IPv4 or IPv6 address of the syslog server.

UDP Port The default syslog server port is 514. If your syslog server uses a different port, configure the

one it uses here.

Log Level Select the severity level(s) of the logs that you want the device to send to this syslog server.

The lower the number, the more critical the logs are.

Add Click Add to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

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Cancel Click Cancel to begin configuring this screen afresh.

Clear Click Clear to return the fields to the factory defaults.

Index This is the index number of a syslog server entry. Click this number to edit the entry.

Active This field displays Yes if the device is to send logs to the syslog server. No displays if the

device is not to send logs to the syslog server.

IP Address This field displays the IP address of the syslog server.

UDP Port This field displays the port of the syslog server.

Log Level This field displays the severity level of the logs that the device is to send to this syslog server.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Delete Click Delete to remove the selected entry(ies).

Cancel Click Cancel to begin configuring this screen afresh.

Table 208 Management > Syslog Setup

LABEL DESCRIPTION

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CHAPTER 48

Cluster Management

48.1 Cluster Management Overview

This chapter introduces cluster management.

Cluster Management allows you to manage switches through one Switch, called the cluster manager.

The switches must be directly connected and be in the same VLAN group so as to be able to

communicate with one another.

In the following example, switch A in the basement is the cluster manager and the other switches on the

upper floors of the building are cluster members.

Figure 307 Clustering Application Example

Table 209 Zyxel Clustering Management Specifications

Maximum number of cluster members 24

Cluster Member Models Must be compatible with Zyxel cluster management implementation.

Cluster Manager The switch through which you manage the cluster member switches.

Cluster Members The switches being managed by the cluster manager switch.

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48.1.1 What You Can Do

• Use the Cluster Management screen (Section 48.2 on page 399) to view the role of the Switch within

the cluster and to access a cluster member switch’s web configurator.

• Use the Clustering Management Configuration screen (Section 48.1 on page 398) to configure

clustering management.

48.2 Cluster Management Status

Use this screen to view the role of the Switch within the cluster and to access a cluster member switch’s

web configurator.

Click Management > Cluster Management in the navigation panel to display the following screen.

Note: A cluster can only have one manager.

Figure 308 Management > Cluster Management: Status

The following table describes the labels in this screen.

Table 210 Management > Cluster Management: Status

LABEL DESCRIPTION

Status This field displays the role of this Switch within the cluster.

Manager

Member (you see this if you access this screen in the cluster member switch directly and not via

the cluster manager)

None (neither a manager nor a member of a cluster)

Manager This field displays the cluster manager switch’s hardware MAC address.

The Number of

Member

This field displays the number of switches that make up this cluster. The following fields describe

the cluster member switches.

Index You can manage cluster member switches via the cluster manager switch. Each number in the

Index column is a hyperlink leading to the cluster member switch’s web configurator (see Figure

310 on page 402).

MacAddr This is the cluster member switch’s hardware MAC address.

Name This is the cluster member switch’s System Name.

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48.3 Clustering Management Configuration

Use this screen to configure clustering management. Click Management > Cluster Management >

Configuration to display the next screen.

Figure 309 Management > Cluster Management > Configuration

The following table describes the labels in this screen.

Model This field displays the model name.

Status This field displays:

Online (the cluster member switch is accessible)

Error (for example the cluster member switch password was changed or the switch was set as the

manager and so left the member list, etc.)

Offline (the switch is disconnected - Offline shows approximately 1.5 minutes after the link

between cluster member and manager goes down)

Table 210 Management > Cluster Management: Status (continued)

LABEL DESCRIPTION

Table 211 Management > Cluster Management > Configuration

LABEL DESCRIPTION

Clustering Manager

Active Select Active to have this Switch become the cluster manager switch. A cluster can only

have one manager. Other (directly connected) switches that are set to be cluster

managers will not be visible in the Clustering Candidates list. If a switch that was previously a

cluster member is later set to become a cluster manager, then its Status is displayed as Error

in the Cluster Management Status screen and a warning icon ( ) appears in the member

summary list below.

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48.4 Technical Reference

This section provides technical background information on the topics discussed in this chapter.

Name Type a name to identify the Clustering Manager. You may use up to 32 printable characters

(spaces are allowed).

VID This is the VLAN ID and is only applicable if the Switch is set to 802.1Q VLAN. All switches must

be directly connected and in the same VLAN group to belong to the same cluster. Switches

that are not in the same VLAN group are not visible in the Clustering Candidates list. This field

is ignored if the Clustering Manager is using Port-based VLAN.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Clustering

Candidate

The following fields relate to the switches that are potential cluster members.

List A list of suitable candidates found by auto-discovery is shown here. The switches must be

directly connected. Directly connected switches that are set to be cluster managers will not

be visible in the Clustering Candidate list. Switches that are not in the same management

VLAN group will not be visible in the Clustering Candidate list.

Password Each cluster member’s password is its web configurator password. Select a member in the

Clustering Candidate list and then enter its web configurator password. If that switch

administrator changes the web configurator password afterwards, then it cannot be

managed from the Cluster Manager. Its Status is displayed as Error in the Cluster

Management Status screen.

If multiple devices have the same password then hold [SHIFT] and click those switches to

select them. Then enter their common web configurator password.

Add Click Add to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to

save your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Refresh Click Refresh to perform auto-discovery again to list potential cluster members.

The next summary table shows the information for the clustering members configured.

Index This is the index number of a cluster member switch.

MacAddr This is the cluster member switch’s hardware MAC address.

Name This is the cluster member switch’s System Name.

Model This is the cluster member switch’s model name.

Select an entry’s check box to select a specific entry. Otherwise, select the check box in the

table heading row to select all entries.

Remove Click the Remove button to remove the selected cluster member switch(es) from the

cluster.

Cancel Click Cancel to begin configuring this screen afresh.

Table 211 Management > Cluster Management > Configuration (continued)

LABEL DESCRIPTION

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48.4.1 Cluster Member Switch Management

Go to the Clustering Management Status screen of the cluster manager switch and then select an Index

hyperlink from the list of members to go to that cluster member switch's web configurator home page.

This cluster member web configurator home page and the home page that you'd see if you accessed it

directly are different.

Figure 310 Cluster Management: Cluster Member Web Configurator Screen

48.4.1.1 Uploading Firmware to a Cluster Member Switch

You can use FTP to upload firmware to a cluster member switch through the cluster manager switch as

shown in the following example.

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Figure 311 Example: Uploading Firmware to a Cluster Member Switch

The following table explains some of the FTP parameters.

C:\>ftp 192.168.1.1

Connected to 192.168.1.1.

220 Switch FTP version 1.0 ready at Thu Jan 1 00:58:46 1970

User (192.168.0.1:(none)): admin

331 Enter PASS command

Password:

230 Logged in

ftp> ls

200 Port command okay

150 Opening data connection for LIST

--w--w--w- 1 owner group 3042210 Jul 01 12:00 ras

-rw-rw-rw- 1 owner group 393216 Jul 01 12:00 config

--w--w--w- 1 owner group 0 Jul 01 12:00 fw-00-a0-c5-01-23-46

-rw-rw-rw- 1 owner group 0 Jul 01 12:00 config-00-a0-c5-01-23-46

226 File sent OK

ftp: 297 bytes received in 0.00Seconds 297000.00Kbytes/sec.

ftp> bin

200 Type I OK

ftp> put 460ABQF0.bin fw-00-a0-c5-01-23-46

200 Port command okay

150 Opening data connection for STOR fw-00-a0-c5-01-23-46

226 File received OK

ftp: 262144 bytes sent in 0.63Seconds 415.44Kbytes/sec.

ftp>

Table 212 FTP Upload to Cluster Member Example

FTP PARAMETER DESCRIPTION

User Enter “admin”.

Password The web configurator password default is 1234.

ls Enter this command to list the name of cluster member switch’s firmware and

configuration file.

460ABQF0.bin This is the name of the firmware file you want to upload to the cluster member

switch.

fw-00-a0-c5-01-23-46 This is the cluster member switch’s firmware name as seen in the cluster

manager switch.

config-00-a0-c5-01-23-46 This is the cluster member switch’s configuration file name as seen in the cluster

manager switch.

Chapter 49 MAC Table

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CHAPTER 49

MAC Table

49.1 MAC Table Overview

This chapter introduces the MAC Table screen.

The MAC Table screen (a MAC table is also known as a filtering database) shows how frames are

forwarded or filtered across the Switch’s ports. It shows what device MAC address, belonging to what

VLAN group (if any) is forwarded to which port(s) and whether the MAC address is dynamic (learned by

the Switch) or static (manually entered in the Static MAC Forwarding screen).

49.1.1 What You Can Do

Use the MAC Table screen (Section 49.2 on page 405) to check whether the MAC address is dynamic or

static.

49.1.2 What You Need to Know

The Switch uses the MAC table to determine how to forward frames. See the following figure.

1The Switch examines a received frame and learns the port on which this source MAC address came.

2The Switch checks to see if the frame's destination MAC address matches a source MAC address

already learned in the MAC table.

• If the Switch has already learned the port for this MAC address, then it forwards the frame to that port.

• If the Switch has not already learned the port for this MAC address, then the frame is flooded to all

ports. Too much port flooding leads to network congestion.

• If the Switch has already learned the port for this MAC address, but the destination port is the same as

the port it came in on, then it filters the frame.

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Figure 312 MAC Table Flowchart

49.2 Viewing the MAC Table

Use this screen to check whether the MAC address is dynamic or static.

Click Management > MAC Table in the navigation panel to display the following screen.

Figure 313 Management > MAC Table

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The following table describes the labels in this screen.

Table 213 Management > MAC Table

LABEL DESCRIPTION

Condition Select one of the buttons and click Search to only display the data which matches the criteria

you specified.

Select All to display any entry in the MAC table of the Switch.

Select Static to display the MAC entries manually configured on the Switch.

Select MAC and enter a MAC address in the field provided to display a specified MAC entry.

Select VID and enter a VLAN ID in the field provided to display the MAC entries belonging to the

specified VLAN.

Select Port and enter a port number in the field provided to display the MAC addresses which

are forwarded on the specified port.

Select Trunk and type the ID of a trunk group to display all MAC addresses learned from the

port(s) in the trunk group.

Sort by Define how the Switch displays and arranges the data in the summary table below.

Select MAC to display and arrange the data according to MAC address.

Select VID to display and arrange the data according to VLAN group.

Select PORT to display and arrange the data according to port number.

Transfer Type Select Dynamic to MAC forwarding and click the Transfer button to change all dynamically

learned MAC address entries in the summary table below into static entries. They also display in

the Static MAC Forwarding screen.

Select Dynamic to MAC filtering and click the Transfer button to change all dynamically learned

MAC address entries in the summary table below into MAC filtering entries. These entries will then

display only in the Filtering screen and the default filtering action is Discard source . The MAC

address(es) will be removed from the MAC table and all traffic sent from the MAC address(es)

will be blocked by the Switch.

Search Click this to search data in the MAC table according to your input criteria.

Transfer Click this to perform the MAC address transferring you selected in the Transfer Type field.

Cancel Click Cancel to change the fields back to their last saved values.

Index This is the incoming frame index number.

MAC Address This is the MAC address of the device from which this incoming frame came.

VID This is the VLAN group to which this frame belongs.

Port This is the port where the above MAC address is forwarded.

Type This shows whether the MAC address is dynamic (learned by the Switch) or static (manually

entered in the Static MAC Forwarding screen).

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CHAPTER 50

ARP Table

50.1 ARP Table Overview

Address Resolution Protocol (ARP) is a protocol for mapping an Internet Protocol address (IP address) to

a physical machine address, also known as a Media Access Control or MAC address, on the local area

network.

An IP (version 4) address is 32 bits long. In an Ethernet LAN, MAC addresses are 48 bits long. The ARP

Table maintains an association between each MAC address and its corresponding IP address.

50.1.1 What You Can Do

Use the ARP Table screen (Section 50.2 on page 407) to view IP-to-MAC address mapping(s).

50.1.2 What You Need to Know

When an incoming packet destined for a host device on a local area network arrives at the Switch, the

Switch's ARP program looks in the ARP Table and if it finds the address, it sends it to the device.

If no entry is found for the IP address, ARP broadcasts the request to all the devices on the LAN. The

Switch fills in its own MAC and IP address in the sender address fields, and puts the known IP address of

the target in the target IP address field. In addition, the Switch puts all ones in the target MAC field

(FF.FF.FF.FF.FF.FF is the Ethernet broadcast address). The replying device (which is either the IP address of

the device being sought or the router that knows the way) replaces the broadcast address with the

target's MAC address, swaps the sender and target pairs, and unicasts the answer directly back to the

requesting machine. ARP updates the ARP Table for future reference and then sends the packet to the

MAC address that replied.

50.2 Viewing the ARP Table

Use the ARP table to view IP-to-MAC address mapping(s) and remove specific dynamic ARP entries.

Click Management > ARP Table in the navigation panel to open the following screen.

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Figure 314 Management > ARP Table

The following table describes the labels in this screen.

Table 214 Management > ARP Table

LABEL DESCRIPTION

Condition Specify how you want the Switch to remove ARP entries when you click Flush.

Select All to remove all of the dynamic entries from the ARP table.

Select IP Address and enter an IP address to remove the dynamic entries learned with the

specified IP address.

Select Port and enter a port number to remove the dynamic entries learned on the specified port.

Flush Click Flush to remove the ARP entries according to the condition you specified.

Cancel Click Cancel to return the fields to the factory defaults.

Index This is the ARP table entry number.

IP Address This is the IP address of a device connected to a Switch port with the corresponding MAC address

below.

MAC Address This is the MAC address of the device with the corresponding IP address above.

VID This field displays the VLAN to which the device belongs.

Port This field displays the port to which the device connects. CPU means this IP address is the Switch’s

management IP address.

Age(s) This field displays how long (in seconds) an entry can still remain in the ARP table before it ages out

and needs to be relearned. This shows 0 for a static entry.

Type This shows whether the IP address is dynamic (learned by the Switch) or static (manually

configured in the Basic Setting > IP Setup or IP Application > ARP Setup > Static ARP screen).

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CHAPTER 51

Path MTU Table

51.1 Path MTU Overview

This chapter introduces the IPv6 Path MTU table.

The largest size (in bytes) of a packet that can be transferred over a data link is called the maximum

transmission unit (MTU). The Switch uses Path MTU Discovery to discover Path MTU (PMTU), that is, the

minimum link MTU of all the links in a path to the destination. If the Switch receives an ICMPv6 Packet Too

Big error message after sending a packet, it fragments the next packet according to the suggested MTU

in the error message.

51.2 Viewing the Path MTU Table

Use this screen to view IPv6 path MTU information on the Switch. Click Management > Path MTU Table in

the navigation panel to display the screen as shown.

Figure 315 Management > Path MTU Table

The following table describes the labels in this screen.

Table 215 Management > Path MTU Table

LABEL DESCRIPTION

Path MTU

aging time

This field displays how long an entry remains in the Path MTU table before it ages out and needs to

be relearned.

Index This field displays the index number of each entry in the table.

Destination

Address

This field displays the destination IPv6 address of each path/entry.

MTU This field displays the maximum transmission unit of the links in the path.

Expire This field displays how long (in minutes) an entry can still remain in the Path MTU table before it

ages out and needs to be relearned.

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CHAPTER 52

Configure Clone

52.1 Overview

This chapter shows you how you can copy the settings of one port onto other ports.

52.2 Configure Clone

Cloning allows you to copy the basic and advanced settings from a source port to a destination port or

ports. Click Management > Configure Clone to open the following screen.

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Figure 316 Management > Configure Clone

The following table describes the labels in this screen.

Table 216 Management > Configure Clone

LABEL DESCRIPTION

Source/

Destination

Port

Enter the destination port or ports under the Destination label. These are the ports which are going

to have the same attributes as the source port. You can enter individual ports separated by a

comma or a range of ports by using a hyphen. For example, 2, 4, 6 indicates that ports 2, 4 and 6

are the destination ports. 2-6 indicates that ports 2 through 6 are the destination ports.

* Select this check box to select all port settings.

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Basic Setting Select which port settings (you configured in the Basic Setting menus) should be copied to the

destination port(s).

Advanced

Application

Select which port settings (you configured in the Advanced Application menus) should be copied

to the destination ports.

Apply Click Apply to save your changes to the Switch’s run-time memory. The Switch loses these

changes if it is turned off or loses power, so use the Save link on the top navigation panel to save

your changes to the non-volatile memory when you are done configuring.

Cancel Click Cancel to begin configuring this screen afresh.

Table 216 Management > Configure Clone (continued)

LABEL DESCRIPTION

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CHAPTER 53

IPv6 Neighbor Table

53.1 IPv6 Neighbor Table Overview

This chapter introduces the IPv6 neighbor table.

An IPv6 host is required to have a neighbor table. If there is an address to be resolved or verified, the

Switch sends out a neighbor solicitation message. When the Switch receives a neighbor advertisement

in response, it stores the neighbor’s link-layer address in the neighbor table. You can also manually

create a static IPv6 neighbor entry using the Basic Setting > IPv6 > IPv6 Configuration > IPv6 Neighbor

Setup screen.

When the Switch needs to send a packet, it first consults other table to determine the next hop. Once

the next hop IPv6 address is known, the Switch looks into the neighbor table to get the link-layer address

and sends the packet when the neighbor is reachable. If the Switch cannot find an entry in the

neighbor table or the state for the neighbor is not reachable, it starts the address resolution process. This

helps reduce the number of IPv6 solicitation and advertisement messages.

53.2 Viewing the IPv6 Neighbor Table

Use this screen to view IPv6 neighbor information on the Switch. Click Management > IPv6 Neighbor

Table in the navigation panel to display the screen as shown.

Figure 317 Management > IPv6 Neighbor Table

The following table describes the labels in this screen.

Table 217 Management > IPv6 Neighbor Table

LABEL DESCRIPTION

Sort by Select this to display and arrange the data according to IPv6 address (Address), MAC address

(MAC) or IPv6 interface (Interface). The information is then displayed in the summary table below.

Index This field displays the index number of each entry in the table.

Address This field displays the IPv6 address of the Switch or a neighboring device.

MAC This field displays the MAC address of the IPv6 interface on which the IPv6 address is configured or

the MAC address of the neighboring device.

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Status This field displays whether the neighbor IPv6 interface is reachable. In IPv6, “reachable” means an

IPv6 packet can be correctly forwarded to a neighbor node (host or router) and the neighbor

can successfully receive and handle the packet. The available options in this field are:

• reachable (R): The interface of the neighboring device is reachable. (The Switch has received

a response to the initial request.)

• stale (S): The last reachable time has expired and the Switch is waiting for a response to

another initial request. The field displays this also when the Switch receives an unrequested

response from the neighbor’s interface.

• delay (D): The neighboring interface is no longer known to be reachable, and traffic has been

sent to the neighbor recently. The Switch delays sending request packets for a short to give

upper-layer protocols a chance to determine reachability.

• probe (P): The Switch is sending request packets and waiting for the neighbor’s response.

• invalid (IV): The neighbor address is with an invalid IPv6 address.

• unknown (?): The status of the neighboring interface can not be determined for some reason.

• incomplete (I): Address resolution is in progress and the link-layer address of the neighbor has

not yet been determined. The interface of the neighboring device did not give a complete

response.

Type This field displays the type of an address mapping to a neighbor interface. The available options in

this field are:

• other (O): none of the following type.

• local (L): A Switch interface is using the address.

• dynamic (D): The IP address to MAC address can be successfully resolved using IPv6 Neighbor

Discovery protocol. Is it similar as IPv4 ARP (Address Resolution protocol).

• static (S): The interface address is statically configured.

Interface This field displays the ID number of the IPv6 interface on which the IPv6 address is created or

through which the neighboring device can be reached.

Table 217 Management > IPv6 Neighbor Table (continued)

LABEL DESCRIPTION

Chapter 54 Port Status

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CHAPTER 54

Port Status

54.1 Overview

This chapter introduces the port status screens.

54.2 Port Status

This screen displays a port statistical summary with links to each port showing statistical details. To view

the port statistics, click Status in all web configurator screens and then the Port Status link in the Quick

Links section of the Status screen to display the Port Status screen as shown next. You can also click

Management > Port Status to see the following screen.

Figure 318 Port Status

The following table describes the labels in this screen.

Table 218 Port Status

LABEL DESCRIPTION

Port This identifies the Ethernet port.

Click a port number to display the Port Details screen (refer to Figure 319 on page 417).

Name This is the name you assigned to this port in the Basic Setting > Port Setup screen.

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54.2.1 Port Details

Click a number in the Port column in the Port Status screen to display individual port statistics. Use this

screen to check status and detailed performance data about an individual port on the Switch.

Link This field displays the speed (either 100M for 100Mbps or1G for 1 Gbps) and the duplex (F for full

duplex or H for half). It also shows the cable type (Copper or Fiber) for the combo ports. This field

displays Down if the port is not connected to any device.

State If STP (Spanning Tree Protocol) is enabled, this field displays the STP state of the port. See Chapter

13 on page 138 for more information.

If STP is disabled, this field displays FORWARDING if the link is up, otherwise, it displays STOP.

When LACP (Link Aggregation Control Protocol), STP, and dot1x are in blocking state, it displays

Blocking.

LACP This fields displays whether LACP (Link Aggregation Control Protocol) has been enabled on the

port.

TxPkts This field shows the number of transmitted frames on this port.

RxPkts This field shows the number of received frames on this port.

Errors This field shows the number of received errors on this port.

Tx KB/s This field shows the number of kilobytes per second transmitted on this port.

Rx KB/s This field shows the number of kilobytes per second received on this port.

Up Time This field shows the total amount of time in hours, minutes and seconds the port has been up.

Clear Counter Select Port, enter a port number and then click Clear Counter to erase the recorded statistical

information for that port, or select Any to clear statistics for all ports.

Table 218 Port Status (continued)

LABEL DESCRIPTION

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Figure 319 Port Status > Port Details

The following table describes the labels in this screen.

Table 219 Port Status: Port Details

LABEL DESCRIPTION

Port Info

Port NO. This field displays the port number you are viewing.

Name This field displays the name of the port.

Link This field displays the speed (either 100M for 100Mbps or 1G for 1 Gbps) and the duplex (F for full

duplex or H for half). It also shows the cable type (Copper or Fiber) for the combo ports. This field

displays Down if the port is not connected to any device.

State If STP (Spanning Tree Protocol) is enabled, this field displays the STP state of the port. See Chapter

13 on page 138 for more information.

If STP is disabled, this field displays FORWARDING if the link is up, otherwise, it displays STOP.

When LACP (Link Aggregation Control Protocol), STP, and dot1x are in blocking state, it displays

Blocking.

LACP This field shows if LACP is enabled on this port or not.

TxPkts This field shows the number of transmitted frames on this port

RxPkts This field shows the number of received frames on this port

Errors This field shows the number of received errors on this port.

Tx KB/s This field shows the number of kilobytes per second transmitted on this port.

Utilization% This field shows the percentage of actual transmitted frames on this port as a percentage of the

Link speed.

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Rx KB/s This field shows the number of kilobytes per second received on this port.

Utilization% This field shows the percentage of actual received frames on this port as a percentage of the Link

speed.

Up Time This field shows the total amount of time the connection has been up.

Tx Packet

The following fields display detailed information about packets transmitted.

Unicast This field shows the number of good unicast packets transmitted.

Multicast This field shows the number of good multicast packets transmitted.

Broadcast This field shows the number of good broadcast packets transmitted.

Pause This field shows the number of 802.3x Pause packets transmitted.

Tagged This field shows the number of packets with VLAN tags transmitted.

Rx Packet

The following fields display detailed information about packets received.

Unicast This field shows the number of good unicast packets received.

Multicast This field shows the number of good multicast packets received.

Broadcast This field shows the number of good broadcast packets received.

Pause This field shows the number of 802.3x Pause packets received.

Control This field shows the number of control packets received (including those with CRC error) but it

does not include the 802.3x Pause packets.

TX Collision

The following fields display information on collisions while transmitting.

Single This is a count of successfully transmitted packets for which transmission is inhibited by exactly one

collision.

Multiple This is a count of successfully transmitted packets for which transmission was inhibited by more

than one collision.

Excessive This is a count of packets for which transmission failed due to excessive collisions. Excessive

collision is defined as the number of maximum collisions before the retransmission count is reset.

Late This is the number of times a late collision is detected, that is, after 512 bits of the packets have

already been transmitted.

Error Packet The following fields display detailed information about packets received that were in error.

RX CRC This field shows the number of packets received with CRC (Cyclic Redundant Check) error(s).

Length This field shows the number of packets received with a length that was out of range.

Runt This field shows the number of packets received that were too short (shorter than 64 octets),

including the ones with CRC errors.

Distribution

64 This field shows the number of packets (including bad packets) received that were 64 octets in

length.

65-127 This field shows the number of packets (including bad packets) received that were between 65

and 127 octets in length.

128-255 This field shows the number of packets (including bad packets) received that were between 128

and 255 octets in length.

256-511 This field shows the number of packets (including bad packets) received that were between 256

and 511 octets in length.

512-1023 This field shows the number of packets (including bad packets) received that were between 512

and 1023 octets in length.

Table 219 Port Status: Port Details (continued)

LABEL DESCRIPTION

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54.2.2 DDMI

Use this screen to view the SFP (Small Form Factor Pluggable) transceiver information. Click

Management > Port Status > DDMI to see the following screen.

Figure 320 Management > Port Status > DDMI

The following table describes the labels in this screen.

54.2.3 DDMI Details

Use this screen to view the real-time SFP (Small Form Factor Pluggable) transceiver information and

operating parameters on the SFP port. The parameters include, for example, transmitting and receiving

power, and module temperature.

1024-1518 This field shows the number of packets (including bad packets) received that were between 1024

and 1518 octets in length.

Giant This field shows the number of packets (including bad packets) received that were between 1519

octets and the maximum frame size.

The maximum frame size varies depending on your switch model.

Table 219 Port Status: Port Details (continued)

LABEL DESCRIPTION

Table 220 Management > Port Status > DDMI

LABEL DESCRIPTION

Port This identifies the SFP port.

Vendor This displays the vendor name of the optical transceiver.

Part Number This displays the part number of the optical transceiver.

Serial Number This displays the serial number of the optical transceiver.

Revision This displays the revision number of the optical transceiver.

Date Code This displays the date when the optical transceiver was manufactured.

Transceiver This displays whether the connection to the optical network is up or down.

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Click a number in the Port column in the DDMI screen to view current transceivers’ status.

Figure 321 DDMI Details

The following table describes the labels in this screen.

Table 221 DDMI Details

LABEL DESCRIPTION

Transceiver Information

Port No This identifies the SFP port.

Connector Type This displays the connector type of the optical transceiver.

Vendor This displays the vendor name of the optical transceiver.

Part Number This displays the part number of the optical transceiver.

Serial Number This displays the serial number of the optical transceiver.

Revision This displays the revision number of the optical transceiver.

Date Code This displays the date when the optical transceiver was manufactured.

Transceiver This displays details about the type of transceiver installed in the SFP slot.

DDMI Information

Type This displays the DDMI parameter.

Temperature

Voltage (V) This displays the level of voltage being supplied to the SFP transceiver.

TX Bias (mA) This displays the milliamps (mA) being supplied to the SFP transceiver’s Laser Diode Transmitter.

TX Power

(dbm) This displays the amount of power the SFP transceiver is transmitting.

RX Power

(dbm) This displays the amount of power the SFP transceiver is receiving from the fiber optic cable.

Current This displays the current status for each monitored DDMI parameter.

High Alarm

Threshold

This displays the high value alarm threshold for each monitored DDMI parameter. An alarm

signal is reported to the Switch if the monitored DDMI parameter reaches this value.

High Warn

Threshold

This displays the high value warning threshold for each monitored DDMI parameter. A warning

signal is reported to the Switch if the monitored DDMI parameter reaches this value.

Low Warn

Threshold

This displays the low value warning threshold for each monitored DDMI parameter. A warning

signal is reported to the Switch if the monitored DDMI parameter reaches this value.

Low Alarm

Threshold

This displays the low value alarm threshold for each monitored DDMI parameter. An alarm

signal is reported to the Switch if the monitored DDMI parameter reaches this value.

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54.2.4 Port Utilization

This screen displays the percentage of actual transmitted or received frames on a port as a percentage

of the Link speed. To view port utilization, click Management > Port Status > Port Utilization to see the

following screen. Alternatively, click Status from any Web Configurator screen and then the Port Status

link in the Quick Links section of the Status screen to display the Port Status screen and then click the

Utilization link tab.

Figure 322 Management > Port Status > Utilization

The following table describes the labels in this screen.

Table 222 Port Status: Utilization

LABEL DESCRIPTION

Port This identifies the Ethernet port.

Link This field displays the speed (either 100M for 100Mbps or 1G for 1 Gbps) and the duplex (F for full

duplex or H for half). It also shows the cable type (Copper or Fiber) for the combo ports. This field

displays Down if the port is not connected to any device.

Tx kB/s This field shows the transmission speed of data sent on this port in kilobytes per second.

Tx Utilization% This field shows the percentage of actual transmitted frames on this port as a percentage of the

Link speed.

Rx KB/s This field shows the transmission speed of data received on this port in kilobytes per second.

Rx Utilization% This field shows the percentage of actual received frames on this port as a percentage of the Link

speed.

422

PART III

Troubleshooting and

Appendices

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CHAPTER 55

Troubleshooting

This chapter offers some suggestions to solve problems you might encounter. The potential problems are

divided into the following categories.

•Power, Hardware Connections, and LEDs

•Switch Access and Login

•Switch Configuration

55.1 Power, Hardware Connections, and LEDs

The Switch does not turn on. None of the LEDs turn on.

1Make sure you are using the power adaptor or cord included with the Switch.

2Make sure the power adaptor or cord is connected to the Switch and plugged in to an appropriate

power source. Make sure the power source is turned on.

3Disconnect and re-connect the power adaptor or cord to the Switch.

4If the problem continues, contact the vendor.

One of the LEDs does not behave as expected.

1Make sure you understand the normal behavior of the LED. See Section 3.3 on page 41.

2Check the hardware connections. See Section 55.1 on page 423.

3Inspect your cables for damage. Contact the vendor to replace any damaged cables.

4Disconnect and re-connect the power adaptor or cord to the Switch.

5If the problem continues, contact the vendor.

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55.2 Switch Access and Login

I forgot the IP address for the Switch.

1The default IP address is http://DHCP-assigned IP or 192.168.1.1.

2If the Switch is removed from a site in Nebula, all the settings in the configuration file are reset to the

Nebula factory defaults except for the IP address. If you changed the default dynamic IP address to a

static IP address while the Switch was in a site in Nebula, the Switch will retain that static IP address after

you remove it from the site in Nebula.

3Use the NCC, the ZON utility, or the console port to find the IP address. The Switch must be registered

and added to a site in Nebula in order for it to be managed using Nebula.

4If this does not work, you have to reset the device to its factory defaults. See Section 4.7 on page 56.

I forgot the username and/or password.

1The default username is admin and the default password is 1234.

2If this does not work, you have to reset the device to its factory defaults. See Section 4.7 on page 56.

I cannot see or access the Login screen in the web configurator.

1Make sure you are using the correct IP address.

• The default IP address is http://DHCP-assigned IP or 192.168.1.1.

• If you changed the IP address, use the new IP address.

• If you changed the IP address and have forgotten it, see the troubleshooting suggestions for I

forgot the IP address for the Switch.

2Check the hardware connections, and make sure the LEDs are behaving as expected. See Section 3.3

on page 41.

3Make sure your Internet browser does not block pop-up windows and has JavaScripts and Java

enabled.

4Make sure your computer is in the same subnet as the Switch. (If you know that there are routers

between your computer and the Switch, skip this step.)

5Reset the device to its factory defaults, and try to access the Switch with the default IP address. See

Section 4.7 on page 56.

6If the problem continues, contact the vendor, or try one of the advanced suggestions.

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Advanced Suggestions

• Try to access the Switch using another service, such as Telnet. If you can access the Switch, check the

remote management settings to find out why the Switch does not respond to HTTP.

I can see the Login screen, but I cannot log in to the Switch.

1Make sure you have entered the user name and password correctly. The default user name is admin,

and the default password is 1234. These fields are case-sensitive, so make sure [Caps Lock] is not on.

2You may have exceeded the maximum number of concurrent Telnet sessions. Close other Telnet

session(s) or try connecting again later.

Check that you have enabled logins for HTTP or Telnet. If you have configured a secured client IP

address, your computer’s IP address must match it. Refer to the chapter on access control for details.

3Disconnect and re-connect the cord to the Switch.

4If this does not work, you have to reset the device to its factory defaults. See Section 4.7 on page 56.

Pop-up Windows, JavaScripts and Java Permissions

In order to use the web configurator you need to allow:

• Web browser pop-up windows from your device.

• JavaScripts (enabled by default).

• Java permissions (enabled by default).

There is unauthorized access to my Switch via telnet, HTTP and SSH.

To avoid unauthorized access, configure the secured client setting in the Management > Access

Control > Remote Management screen for telnet, HTTP and SSH (see Section 44.6 on page 380).

Computers not belonging to the secured client set cannot get permission to access the Switch.

55.3 Switch Configuration

I lost my configuration settings after I restart the Switch.

Make sure you save your configuration into the Switch’s

nonvolatile memory each time you make changes. Click

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Save at the top right corner of the web configurator to save the configuration permanently. See also

Section 43.8 on page 364 for more information about how to save your configuration.

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APPENDIX A

Customer Support

In the event of problems that cannot be solved by using this manual, you should contact your vendor. If

you cannot contact your vendor, then contact a Zyxel office for the region in which you bought the

device.

See https://www.zyxel.com/homepage.shtml and also

https://www.zyxel.com/about_zyxel/zyxel_worldwide.shtml for the latest information.

Please have the following information ready when you contact an office.

Required Information

• Product model and serial number.

• Warranty Information.

• Date that you received your device.

• Brief description of the problem and the steps you took to solve it.

Corporate Headquarters (Worldwide)

Taiwan

• Zyxel Communications Corporation

• https://www.zyxel.com

Asia

China

• Zyxel Communications (Shanghai) Corp.

Zyxel Communications (Beijing) Corp.

Zyxel Communications (Tianjin) Corp.

• https://www.zyxel.com/cn/zh/

India

•Zyxel Technology India Pvt Ltd

• https://www.zyxel.com/in/en/

Kazakhstan

•Zyxel Kazakhstan

• https://www.zyxel.kz

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Korea

• Zyxel Korea Corp.

• http://www.zyxel.kr

Malaysia

• Zyxel Malaysia Sdn Bhd.

• http://www.zyxel.com.my

Pakistan

• Zyxel Pakistan (Pvt.) Ltd.

• http://www.zyxel.com.pk

Philippines

• Zyxel Philippines

• http://www.zyxel.com.ph

Singapore

• Zyxel Singapore Pte Ltd.

• http://www.zyxel.com.sg

Taiwan

• Zyxel Communications Corporation

• https://www.zyxel.com/tw/zh/

Thailand

• Zyxel Thailand Co., Ltd

• https://www.zyxel.com/th/th/

Vietnam

• Zyxel Communications Corporation-Vietnam Office

• https://www.zyxel.com/vn/vi

Europe

Belarus

•Zyxel BY

• https://www.zyxel.by

Belgium

• Zyxel Communications B.V.

• https://www.zyxel.com/be/nl/

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• https://www.zyxel.com/be/fr/

Bulgaria

•Zyxel България

• https://www.zyxel.com/bg/bg/

Czech Republic

• Zyxel Communications Czech s.r.o

• https://www.zyxel.com/cz/cs/

Denmark

• Zyxel Communications A/S

• https://www.zyxel.com/dk/da/

Estonia

• Zyxel Estonia

• https://www.zyxel.com/ee/et/

Finland

• Zyxel Communications

• https://www.zyxel.com/fi/fi/

France

•Zyxel France

• https://www.zyxel.fr

Germany

•Zyxel Deutschland GmbH

• https://www.zyxel.com/de/de/

Hungary

• Zyxel Hungary & SEE

• https://www.zyxel.com/hu/hu/

Italy

• Zyxel Communications Italy

• https://www.zyxel.com/it/it/

Latvia

•Zyxel Latvia

• https://www.zyxel.com/lv/lv/

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Lithuania

•Zyxel Lithuania

• https://www.zyxel.com/lt/lt/

Netherlands

• Zyxel Benelux

• https://www.zyxel.com/nl/nl/

Norway

• Zyxel Communications

• https://www.zyxel.com/no/no/

Poland

• Zyxel Communications Poland

• https://www.zyxel.com/pl/pl/

Romania

• Zyxel Romania

• https://www.zyxel.com/ro/ro

Russia

• Zyxel Russia

• https://www.zyxel.com/ru/ru/

Slovakia

• Zyxel Communications Czech s.r.o. organizacna zlozka

• https://www.zyxel.com/sk/sk/

Spain

• Zyxel Communications ES Ltd

• https://www.zyxel.com/es/es/

Sweden

• Zyxel Communications

• https://www.zyxel.com/se/sv/

Switzerland

•Studerus AG

• https://www.zyxel.ch/de

• https://www.zyxel.ch/fr

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Turkey

• Zyxel Turkey A.S.

• https://www.zyxel.com/tr/tr/

• Zyxel Communications UK Ltd.

• https://www.zyxel.com/uk/en/

Ukraine

•Zyxel Ukraine

• http://www.ua.zyxel.com

South America

Argentina

• Zyxel Communications Corporation

• https://www.zyxel.com/co/es/

Brazil

• Zyxel Communications Brasil Ltda.

• https://www.zyxel.com/br/pt/

Colombia

• Zyxel Communications Corporation

• https://www.zyxel.com/co/es/

Ecuador

• Zyxel Communications Corporation

• https://www.zyxel.com/co/es/

South America

• Zyxel Communications Corporation

• https://www.zyxel.com/co/es/

Middle East

Israel

• Zyxel Communications Corporation

• http://il.zyxel.com/

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Middle East

• Zyxel Communications Corporation

• https://www.zyxel.com/me/en/

North America

USA

• Zyxel Communications, Inc. - North America Headquarters

• https://www.zyxel.com/us/en/

Oceania

Australia

• Zyxel Communications Corporation

• https://www.zyxel.com/au/en/

Africa

South Africa

• Nology (Pty) Ltd.

• https://www.zyxel.com/za/en/

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APPENDIX B

Common Services

The following table lists some commonly-used services and their associated protocols and port numbers.

For a comprehensive list of port numbers, ICMP type/code numbers and services, visit the IANA (Internet

Assigned Number Authority) web site.

•Name: This is a short, descriptive name for the service. You can use this one or create a different one,

if you like.

•Protocol: This is the type of IP protocol used by the service. If this is TCP/UDP, then the service uses the

same port number with TCP and UDP. If this is User-Defined, the Port(s) is the IP protocol number, not

the port number.

•Port(s): This value depends on the Protocol. Please refer to RFC 1700 for further information about port

numbers.

•If the Protocol is TCP, UDP, or TCP/UDP, this is the IP port number.

•If the Protocol is USER, this is the IP protocol number.

•Description: This is a brief explanation of the applications that use this service or the situations in which

this service is used.

Table 223 Commonly Used Services

NAME PROTOCOL PORT(S) DESCRIPTION

AH (IPSEC_TUNNEL) User-Defined 51 The IPSEC AH (Authentication Header) tunneling

protocol uses this service.

AIM/New-ICQ TCP 5190 AOL’s Internet Messenger service. It is also used as a

listening port by ICQ.

AUTH TCP 113 Authentication protocol used by some servers.

BGP TCP 179 Border Gateway Protocol.

BOOTP_CLIENT UDP 68 DHCP Client.

BOOTP_SERVER UDP 67 DHCP Server.

CU-SEEME TCP

UDP

7648

24032

A popular videoconferencing solution from White

Pines Software.

DNS TCP/UDP 53 Domain Name Server, a service that matches web

names (for example www.zyxel.com) to IP numbers.

ESP (IPSEC_TUNNEL) User-Defined 50 The IPSEC ESP (Encapsulation Security Protocol)

tunneling protocol uses this service.

FINGER TCP 79 Finger is a UNIX or Internet related command that can

be used to find out if a user is logged on.

FTP TCP

TCP

File Transfer Program, a program to enable fast transfer

of files, including large files that may not be possible by

e-mail.

H.323 TCP 1720 NetMeeting uses this protocol.

HTTP TCP 80 Hyper Text Transfer Protocol - a client/server protocol

for the world wide web.

HTTPS TCP 443 HTTPS is a secured http session often used in e-

commerce.

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ICMP User-Defined 1Internet Control Message Protocol is often used for

diagnostic or routing purposes.

ICQ UDP 4000 This is a popular Internet chat program.

IGMP (MULTICAST) User-Defined 2Internet Group Multicast Protocol is used when

sending packets to a specific group of hosts.

IKE UDP 500 The Internet Key Exchange algorithm is used for key

distribution and management.

IRC TCP/UDP 6667 This is another popular Internet chat program.

MSN Messenger TCP 1863 Microsoft Networks’ messenger service uses this

protocol.

NEW-ICQ TCP 5190 An Internet chat program.

NEWS TCP 144 A protocol for news groups.

NFS UDP 2049 Network File System - NFS is a client/server distributed

file service that provides transparent file sharing for

network environments.

NNTP TCP 119 Network News Transport Protocol is the delivery

mechanism for the USENET newsgroup service.

PING User-Defined 1Packet INternet Groper is a protocol that sends out

ICMP echo requests to test whether or not a remote

host is reachable.

POP3 TCP 110 Post Office Protocol version 3 lets a client computer

get e-mail from a POP3 server through a temporary

connection (TCP/IP or other).

PPTP TCP 1723 Point-to-Point Tunneling Protocol enables secure

transfer of data over public networks. This is the control

channel.

PPTP_TUNNEL (GRE) User-Defined 47 PPTP (Point-to-Point Tunneling Protocol) enables

secure transfer of data over public networks. This is the

data channel.

RCMD TCP 512 Remote Command Service.

REAL_AUDIO TCP 7070 A streaming audio service that enables real time

sound over the web.

REXEC TCP 514 Remote Execution Daemon.

RLOGIN TCP 513 Remote Login.

RTELNET TCP 107 Remote Telnet.

RTSP TCP/UDP 554 The Real Time Streaming (media control) Protocol

(RTSP) is a remote control for multimedia on the

Internet.

SFTP TCP 115 Simple File Transfer Protocol.

SMTP TCP 25 Simple Mail Transfer Protocol is the message-exchange

standard for the Internet. SMTP enables you to move

messages from one e-mail server to another.

SNMP TCP/UDP 161 Simple Network Management Program.

SNMP-TRAPS TCP/UDP 162 Traps for use with the SNMP (RFC:1215).

SQL-NET TCP 1521 Structured Query Language is an interface to access

data on many different types of database systems,

including mainframes, midrange systems, UNIX systems

and network servers.

Table 223 Commonly Used Services (continued)

NAME PROTOCOL PORT(S) DESCRIPTION

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SSH TCP/UDP 22 Secure Shell Remote Login Program.

STRM WORKS UDP 1558 Stream Works Protocol.

SYSLOG UDP 514 Syslog allows you to send system logs to a UNIX server.

TACACS UDP 49 Login Host Protocol used for (Terminal Access

Controller Access Control System).

TELNET TCP 23 Telnet is the login and terminal emulation protocol

common on the Internet and in UNIX environments. It

operates over TCP/IP networks. Its primary function is to

allow users to log into remote host systems.

TFTP UDP 69 Trivial File Transfer Protocol is an Internet file transfer

protocol similar to FTP, but uses the UDP (User

Datagram Protocol) rather than TCP (Transmission

Control Protocol).

VDOLIVE TCP 7000 Another videoconferencing solution.

Table 223 Commonly Used Services (continued)

NAME PROTOCOL PORT(S) DESCRIPTION

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APPENDIX C

IPv6

Overview

IPv6 (Internet Protocol version 6), is designed to enhance IP address size and features. The increase in

IPv6 address size to 128 bits (from the 32-bit IPv4 address) allows up to 3.4 x 1038 IP addresses.

IPv6 Addressing

The 128-bit IPv6 address is written as eight 16-bit hexadecimal blocks separated by colons (:). This is an

example IPv6 address 2001:0db8:1a2b:0015:0000:0000:1a2f:0000.

IPv6 addresses can be abbreviated in two ways:

• Leading zeros in a block can be omitted. So 2001:0db8:1a2b:0015:0000:0000:1a2f:0000 can be

written as 2001:db8:1a2b:15:0:0:1a2f:0.

• Any number of consecutive blocks of zeros can be replaced by a double colon. A double colon can

only appear once in an IPv6 address. So 2001:0db8:0000:0000:1a2f:0000:0000:0015 can be

written as 2001:0db8::1a2f:0000:0000:0015, 2001:0db8:0000:0000:1a2f::0015,

2001:db8::1a2f:0:0:15 or 2001:db8:0:0:1a2f::15.

Prefix and Prefix Length

Similar to an IPv4 subnet mask, IPv6 uses an address prefix to represent the network address. An IPv6

prefix length specifies how many most significant bits (start from the left) in the address compose the

network address. The prefix length is written as “/x” where x is a number. For example,

2001:db8:1a2b:15::1a2f:0/32

means that the first 32 bits (2001:db8) is the subnet prefix.

Link-local Address

A link-local address uniquely identifies a device on the local network (the LAN). It is similar to a “private IP

address” in IPv4. You can have the same link-local address on multiple interfaces on a device. A link-

local unicast address has a predefined prefix of fe80::/10. The link-local unicast address format is as

follows.

Table 224 Link-local Unicast Address Format

Global Address

A global address uniquely identifies a device on the Internet. It is similar to a “public IP address” in IPv4. A

global unicast address starts with a 2 or 3.

1111 1110 10 0 Interface ID

10 bits 54 bits 64 bits

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Unspecified Address

An unspecified address (0:0:0:0:0:0:0:0 or ::) is used as the source address when a device does not have

its own address. It is similar to “0.0.0.0” in IPv4.

Loopback Address

A loopback address (0:0:0:0:0:0:0:1 or ::1) allows a host to send packets to itself. It is similar to “127.0.0.1”

in IPv4.

Multicast Address

In IPv6, multicast addresses provide the same functionality as IPv4 broadcast addresses. Broadcasting is

not supported in IPv6. A multicast address allows a host to send packets to all hosts in a multicast group.

Multicast scope allows you to determine the size of the multicast group. A multicast address has a

predefined prefix of ff00::/8. The following table describes some of the predefined multicast addresses.

The following table describes the multicast addresses which are reserved and can not be assigned to a

multicast group.

Table 225 Predefined Multicast Address

MULTICAST ADDRESS DESCRIPTION

FF01:0:0:0:0:0:0:1 All hosts on a local node.

FF01:0:0:0:0:0:0:2 All routers on a local node.

FF02:0:0:0:0:0:0:1 All hosts on a local connected link.

FF02:0:0:0:0:0:0:2 All routers on a local connected link.

FF05:0:0:0:0:0:0:2 All routers on a local site.

FF05:0:0:0:0:0:1:3 All DHCP severs on a local site.

Table 226 Reserved Multicast Address

MULTICAST ADDRESS

FF00:0:0:0:0:0:0:0

FF01:0:0:0:0:0:0:0

FF02:0:0:0:0:0:0:0

FF03:0:0:0:0:0:0:0

FF04:0:0:0:0:0:0:0

FF05:0:0:0:0:0:0:0

FF06:0:0:0:0:0:0:0

FF07:0:0:0:0:0:0:0

FF08:0:0:0:0:0:0:0

FF09:0:0:0:0:0:0:0

FF0A:0:0:0:0:0:0:0

FF0B:0:0:0:0:0:0:0

FF0C:0:0:0:0:0:0:0

FF0D:0:0:0:0:0:0:0

FF0E:0:0:0:0:0:0:0

FF0F:0:0:0:0:0:0:0

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Subnet Masking

Both an IPv6 address and IPv6 subnet mask compose of 128-bit binary digits, which are divided into

eight 16-bit blocks and written in hexadecimal notation. Hexadecimal uses four bits for each character

(1 ~ 10, A ~ F). Each block’s 16 bits are then represented by four hexadecimal characters. For example,

FFFF:FFFF:FFFF:FFFF:FC00:0000:0000:0000.

Interface ID

In IPv6, an interface ID is a 64-bit identifier. It identifies a physical interface (for example, an Ethernet

port) or a virtual interface (for example, the management IP address for a VLAN). One interface should

have a unique interface ID.

EUI-64

The EUI-64 (Extended Unique Identifier) defined by the IEEE (Institute of Electrical and Electronics

Engineers) is an interface ID format designed to adapt with IPv6. It is derived from the 48-bit (6-byte)

Ethernet MAC address as shown next. EUI-64 inserts the hex digits fffe between the third and fourth bytes

of the MAC address and complements the seventh bit of the first byte of the MAC address. See the

following example.

Stateless Autoconfiguration

With stateless autoconfiguration in IPv6, addresses can be uniquely and automatically generated.

Unlike DHCPv6 (Dynamic Host Configuration Protocol version six) which is used in IPv6 stateful

autoconfiguration, the owner and status of addresses don’t need to be maintained by a DHCP server.

Every IPv6 device is able to generate its own and unique IP address automatically when IPv6 is initiated

on its interface. It combines the prefix and the interface ID (generated from its own Ethernet MAC

address, see Interface ID and EUI-64) to form a complete IPv6 address.

When IPv6 is enabled on a device, its interface automatically generates a link-local address (beginning

with fe80).

When the interface is connected to a network with a router and the Switch is set to automatically obtain

an IPv6 network prefix from the router for the interface, it generates 3another address which combines

its interface ID and global and subnet information advertised from the router. This is a routable global IP

address.

DHCPv6

The Dynamic Host Configuration Protocol for IPv6 (DHCPv6, RFC 3315) is a server-client protocol that

allows a DHCP server to assign and pass IPv6 network addresses, prefixes and other configuration

information to DHCP clients. DHCPv6 servers and clients exchange DHCP messages using UDP.

Table 227

MAC 00 : 13 : 49 : 12 : 34 : 56

Table 228

EUI-64 02: 13 : 49 : FF : FE : 12 : 34 : 56

3. In IPv6, all network interfaces can be associated with several addresses.

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Each DHCP client and server has a unique DHCP Unique IDentifier (DUID), which is used for identification

when they are exchanging DHCPv6 messages. The DUID is generated from the MAC address, time,

vendor assigned ID and/or the vendor's private enterprise number registered with the IANA. It should not

change over time even after you reboot the device.

Identity Association

An Identity Association (IA) is a collection of addresses assigned to a DHCP client, through which the

server and client can manage a set of related IP addresses. Each IA must be associated with exactly

one interface. The DHCP client uses the IA assigned to an interface to obtain configuration from a DHCP

server for that interface. Each IA consists of a unique IAID and associated IP information.

The IA type is the type of address in the IA. Each IA holds one type of address. IA_NA means an identity

association for non-temporary addresses and IA_TA is an identity association for temporary addresses.

An IA_NA option contains the T1 and T2 fields, but an IA_TA option does not. The DHCPv6 server uses T1

and T2 to control the time at which the client contacts with the server to extend the lifetimes on any

addresses in the IA_NA before the lifetimes expire. After T1, the client sends the server (S1) (from which

the addresses in the IA_NA were obtained) a Renew message. If the time T2 is reached and the server

does not respond, the client sends a Rebind message to any available server (S2). For an IA_TA, the

client may send a Renew or Rebind message at the client's discretion.

DHCP Relay Agent

A DHCP relay agent is on the same network as the DHCP clients and helps forward messages between

the DHCP server and clients. When a client cannot use its link-local address and a well-known multicast

address to locate a DHCP server on its network, it then needs a DHCP relay agent to send a message to

a DHCP server that is not attached to the same network.

The DHCP relay agent can add the remote identification (remote-ID) option and the interface-ID option

to the Relay-Forward DHCPv6 messages. The remote-ID option carries a user-defined string, such as the

system name. The interface-ID option provides slot number, port information and the VLAN ID to the

DHCPv6 server. The remote-ID option (if any) is stripped from the Relay-Reply messages before the relay

agent sends the packets to the clients. The DHCP server copies the interface-ID option from the Relay-

Forward message into the Relay-Reply message and sends it to the relay agent. The interface-ID should

not change even after the relay agent restarts.

Prefix Delegation

Prefix delegation enables an IPv6 router to use the IPv6 prefix (network address) received from the ISP (or

a connected uplink router) for its LAN. The Switch uses the received IPv6 prefix (for example, 2001:db2::/

48) to generate its LAN IP address. Through sending Router Advertisements (RAs) regularly by multicast,

the Switch passes the IPv6 prefix information to its LAN hosts. The hosts then can use the prefix to

generate their IPv6 addresses.

Renew Rebind

Rebind

to S1

Renew

to S1

Renew

to S1

Renew

to S1

Renew

to S1

Renew

to S1

to S2

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ICMPv6

Internet Control Message Protocol for IPv6 (ICMPv6 or ICMP for IPv6) is defined in RFC 4443. ICMPv6 has

a preceding Next Header value of 58, which is different from the value used to identify ICMP for IPv4.

ICMPv6 is an integral part of IPv6. IPv6 nodes use ICMPv6 to report errors encountered in packet

processing and perform other diagnostic functions, such as "ping".

Neighbor Discovery Protocol (NDP)

The Neighbor Discovery Protocol (NDP) is a protocol used to discover other IPv6 devices and track

neighbor’s reachability in a network. An IPv6 device uses the following ICMPv6 messages types:

• Neighbor solicitation: A request from a host to determine a neighbor’s link-layer address (MAC

address) and detect if the neighbor is still reachable. A neighbor being “reachable” means it

responds to a neighbor solicitation message (from the host) with a neighbor advertisement message.

• Neighbor advertisement: A response from a node to announce its link-layer address.

• Router solicitation: A request from a host to locate a router that can act as the default router and

forward packets.

• Router advertisement: A response to a router solicitation or a periodical multicast advertisement from

a router to advertise its presence and other parameters.

IPv6 Cache

An IPv6 host is required to have a neighbor cache, destination cache, prefix list and default router list.

The Switch maintains and updates its IPv6 caches constantly using the information from response

messages. In IPv6, the Switch configures a link-local address automatically, and then sends a neighbor

solicitation message to check if the address is unique. If there is an address to be resolved or verified, the

Switch also sends out a neighbor solicitation message. When the Switch receives a neighbor

advertisement in response, it stores the neighbor’s link-layer address in the neighbor cache. When the

Switch uses a router solicitation message to query for a router and receives a router advertisement

message, it adds the router’s information to the neighbor cache, prefix list and destination cache. The

Switch creates an entry in the default router list cache if the router can be used as a default router.

When the Switch needs to send a packet, it first consults the destination cache to determine the next

hop. If there is no matching entry in the destination cache, the Switch uses the prefix list to determine

whether the destination address is on-link and can be reached directly without passing through a router.

If the address is onlink, the address is considered as the next hop. Otherwise, the Switch determines the

next-hop from the default router list or routing table. Once the next hop IP address is known, the Switch

looks into the neighbor cache to get the link-layer address and sends the packet when the neighbor is

reachable. If the Switch cannot find an entry in the neighbor cache or the state for the neighbor is not

reachable, it starts the address resolution process. This helps reduce the number of IPv6 solicitation and

advertisement messages.

Multicast Listener Discovery

The Multicast Listener Discovery (MLD) protocol (defined in RFC 2710) is derived from IPv4's Internet

Group Management Protocol version 2 (IGMPv2). MLD uses ICMPv6 message types, rather than IGMP

message types. MLDv1 is equivalent to IGMPv2 and MLDv2 is equivalent to IGMPv3.

MLD allows an IPv6 switch or router to discover the presence of MLD listeners who wish to receive

multicast packets and the IP addresses of multicast groups the hosts want to join on its network.

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MLD snooping and MLD proxy are analogous to IGMP snooping and IGMP proxy in IPv4.

MLD filtering controls which multicast groups a port can join.

MLD Messages

A multicast router or switch periodically sends general queries to MLD hosts to update the multicast

forwarding table. When an MLD host wants to join a multicast group, it sends an MLD Report message

for that address.

An MLD Done message is equivalent to an IGMP Leave message. When an MLD host wants to leave a

multicast group, it can send a Done message to the router or switch. The router or switch then sends a

group-specific query to the port on which the Done message is received to determine if other devices

connected to this port should remain in the group.

Example - Enabling IPv6 on Windows XP/2003/Vista

By default, Windows XP and Windows 2003 support IPv6. This example shows you how to use the ipv6

install command on Windows XP/2003 to enable IPv6. This also displays how to use the ipconfig

command to see auto-generated IP addresses.

IPv6 is installed and enabled by default in Windows Vista. Use the ipconfig command to check your

automatic configured IPv6 address as well. You should see at least one IPv6 address available for the

interface on your computer.

Example - Enabling DHCPv6 on Windows XP

Windows XP does not support DHCPv6. If your network uses DHCPv6 for IP address assignment, you have

to additionally install a DHCPv6 client software on your Windows XP. (Note: If you use static IP addresses

or Router Advertisement for IPv6 address assignment in your network, ignore this section.)

This example uses Dibbler as the DHCPv6 client. To enable DHCPv6 client on your computer:

1Install Dibbler and select the DHCPv6 client option on your computer.

C:\>ipv6 install

Installing...

Succeeded.

C:\>ipconfig

Windows IP Configuration

Ethernet adapter Local Area Connection:

Connection-specific DNS Suffix . :

IP Address. . . . . . . . . . . . : 10.1.1.46

Subnet Mask . . . . . . . . . . . : 255.255.255.0

IP Address. . . . . . . . . . . . : fe80::2d0:59ff:feb8:103c%4

Default Gateway . . . . . . . . . : 10.1.1.254

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2After the installation is complete, select Start > All Programs > Dibbler-DHCPv6 > Client Install as service.

3Select Start > Control Panel > Administrative Tools > Services.

4Double click Dibbler - a DHCPv6 client.

5Click Start and then OK.

6Now your computer can obtain an IPv6 address from a DHCPv6 server.

Example - Enabling IPv6 on Windows 7

Windows 7 supports IPv6 by default. DHCPv6 is also enabled when you enable IPv6 on a Windows 7

computer.

To enable IPv6 in Windows 7:

1Select Control Panel > Network and Sharing Center > Local Area Connection.

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2Select the Internet Protocol Version 6 (TCP/IPv6) checkbox to enable it.

3Click OK to save the change.

4Click Close to exit the Local Area Connection Status screen.

5Select Start > All Programs > Accessories > Command Prompt.

6Use the ipconfig command to check your dynamic IPv6 address. This example shows a global address

(2001:b021:2d::1000) obtained from a DHCP server.

C:\>ipconfig

Windows IP Configuration

Ethernet adapter Local Area Connection:

Connection-specific DNS Suffix . :

IPv6 Address. . . . . . . . . . . : 2001:b021:2d::1000

Link-local IPv6 Address . . . . . : fe80::25d8:dcab:c80a:5189%11

IPv4 Address. . . . . . . . . . . : 172.16.100.61

Subnet Mask . . . . . . . . . . . : 255.255.255.0

Default Gateway . . . . . . . . . : fe80::213:49ff:feaa:7125%11

172.16.100.254

GS2220 Series User’s Guide

444

APPENDIX D

Legal Information

The contents of this publication may not be reproduced in any part or as a whole, transcribed, stored in a retrieval system, translated into any

language, or transmitted in any form or by any means, electronic, mechanical, magnetic, optical, chemical, photocopying, manual, or

otherwise, without the prior written permission of Zyxel Communications Corporation.

Disclaimer

Zyxel does not assume any liability arising out of the application or use of any products, or software described herein. Neither does it convey any

license under its patent rights nor the patent rights of others. Zyxel further reserves the right to make changes in any products described herein

without notice. This publication is subject to change without notice.

Regulatory Notice and Statement

United States of America

The following information applies if you use the product within USA area.

Federal Communications Commission (FCC) EMC Statement

• This device complies with Part 15 of FCC rules. Operation is subject to the following two conditions:

(1) This device may not cause harmful interference.

(2) This device must accept any interference received, including interference that may cause undesired operations.

• Changes or modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate the

equipment.

• This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to part 15 of the FCC Rules. These

limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial

environment. This equipment generates, uses, and can radiate radio frequency energy and, if not installed and used in accordance with the

instruction manual, may cause harmful interference to radio communications. Operation of this equipment in a residential area is likely to

cause harmful interference in which case the user will be required to correct the interference at his own expense.

Canada

The following information applies if you use the product within Canada area

Innovation, Science, and Economic Development Canada ICES Statement

CAN ICES-3 (A)/NMB-3(A)

European Union

The following information applies if you use the product within the European Union.

CE EMC statement

WARNING: This equipment is compliant with Class A of EN55032. In a residential environment this equipment may cause radio interference.

Appendix D Legal Information

GS2220 Series User’s Guide

445

List of National Codes

Safety Warnings

• Do NOT use this product near water, for example, in a wet basement or near a swimming pool.

• Do NOT expose your device to dampness, dust or corrosive liquids.

• Do NOT store things on the device.

• Do not obstruct the device ventillation slots as insufficient airflow may harm your device. For example, do not place the device in an

enclosed space such as a box or on a very soft surface such as a bed or sofa.

• Do NOT install, use, or service this device during a thunderstorm. There is a remote risk of electric shock from lightning.

• Connect ONLY suitable accessories to the device.

• Do NOT open the device or unit. Opening or removing covers can expose you to dangerous high voltage points or other risks. ONLY qualified

service personnel should service or disassemble this device. Please contact your vendor for further information.

• Make sure to connect the cables to the correct ports.

• Place connecting cables carefully so that no one will step on them or stumble over them.

• Always disconnect all cables from this device before servicing or disassembling.

• Use ONLY an appropriate power adaptor or cord for your device. Connect it to the right supply voltage (for example, 110V AC in North

America or 230V AC in Europe).

• DO NOT remove the plug and connect it to a power outlet by itself; always attach the plug to the power adaptor first before connecting it to

a power outlet.

• Do NOT allow anything to rest on the power adaptor or cord and do NOT place the product where anyone can walk on the power adaptor

or cord.

• Do NOT use the device if the power adaptor or cord is damaged as it might cause electrocution.

• If the power adaptor or cord is damaged, remove it from the device and the power source.

• Do NOT attempt to repair the power adaptor or cord. Contact your local vendor to order a new one.

• DO NOT use the device outside, and make sure all the connections are indoors. There is a remote risk of electric shock from lightning.

• CAUTION: RISK OF EXPLOSION IF BATTERY (on the motherboard) IS REPLACED BY AN INCORRECT TYPE. DISPOSE OF USED BATTERIES

ACCORDING TO THE INSTRUCTIONS. Dispose them at the applicable collection point for the recycling of electrical and electronic equipment.

For detailed information about recycling of this product, please contact your local city office, your household waste disposal service or the

store where you purchased the product.

• Use ONLY power wires of the appropriate wire gauge for your device. Connect it to a power supply of the correct voltage.

• Fuse Warning! Replace a fuse only with a fuse of the same type and rating.

• The POE (Power over Ethernet) devices that supply or receive power and their connected Ethernet cables must all be completely indoors.

• This equipment must be grounded. Never defeat the ground conductor or operate the equipment in the absence of a suitably installed

ground conductor. Contact the appropriate electrical inspection authority or an electrician if you are uncertain that suitable grounding is

available.

• When connecting or disconnecting power to hot-pluggable power supplies, if offered with your system, observe the following guidelines:

- Install the power supply before connecting the power cable to the power supply.

- Unplug the power cable before removing the power supply.

- If the system has multiple sources of power, disconnect power from the system by unplugging all power cables from the power supply.

• The following warning statements apply, where the disconnect device is not incorporated in the equipment or where the plug on the power

supply cord is intended to serve as the disconnect device,

- For PERMANENTLY CONNECTED EQUIPMENT, a readily accessible disconnect device shall be incorporated external to the equipment;

- For PLUGGABLE EQUIPMENT, the socket-outlet shall be installed near the equipment and shall be easily accessible.

• CLASS 1 LASER PRODUCT

• APPAREIL À LASER DE CLASS 1

• PRODUCT COMPLIES WITH 21 CFR 1040.10 AND 1040.11.

• PRODUIT CONFORME SELON 21 CFR 1040.10 ET 1040.11.

COUNTRY ISO 3166 2 LETTER CODE COUNTRY ISO 3166 2 LETTER CODE

Austria AT Liechtenstein LI

Belgium BE Lithuania LT

Bulgaria BG Luxembourg LU

Croatia HR Malta MT

Cyprus CY Netherlands NL

Czech Republic CR Norway NO

Denmark DK Poland PL

Estonia EE Portugal PT

Finland FI Romania RO

France FR Serbia RS

Germany DE Slovakia SK

Greece GR Slovenia SI

Hungary HU Spain ES

Iceland IS Sweden SE

Ireland IE Switzerland CH

Italy IT Turkey TR

Latvia LV United Kingdom GB

Appendix D Legal Information

GS2220 Series User’s Guide

446

Environment Statement

European Union - Disposal and Recycling Information

The symbol below means that according to local regulations your product and/or its battery shall be disposed of separately from domestic

waste. If this product is end of life, take it to a recycling station designated by local authorities. At the time of disposal, the separate collection of

your product and/or its battery will help save natural resources and ensure that the environment is sustainable development.

Die folgende Symbol bedeutet, dass Ihr Produkt und/oder seine Batterie gemäß den örtlichen Bestimmungen getrennt vom Hausmüll entsorgt

werden muss. Wenden Sie sich an eine Recyclingstation, wenn dieses Produkt das Ende seiner Lebensdauer erreicht hat. Zum Zeitpunkt der

Entsorgung wird die getrennte Sammlung von Produkt und/oder seiner Batterie dazu beitragen, natürliche Ressourcen zu sparen und die Umwelt

und die menschliche Gesundheit zu schützen.

El símbolo de abajo indica que según las regulaciones locales, su producto y/o su batería deberán depositarse como basura separada de la

doméstica. Cuando este producto alcance el final de su vida útil, llévelo a un punto limpio. Cuando llegue el momento de desechar el

producto, la recogida por separado éste y/o su batería ayudará a salvar los recursos naturales y a proteger la salud humana y

medioambiental.

Le symbole ci-dessous signifie que selon les réglementations locales votre produit et/ou sa batterie doivent être éliminés séparément des ordures

ménagères. Lorsque ce produit atteint sa fin de vie, amenez-le à un centre de recyclage. Au moment de la mise au rebut, la collecte séparée

de votre produit et/ou de sa batterie aidera à économiser les ressources naturelles et protéger l'environnement et la santé humaine.

Il simbolo sotto significa che secondo i regolamenti locali il vostro prodotto e/o batteria deve essere smaltito separatamente dai rifiuti domestici.

Quando questo prodotto raggiunge la fine della vita di servizio portarlo a una stazione di riciclaggio. Al momento dello smaltimento, la raccolta

separata del vostro prodotto e/o della sua batteria aiuta a risparmiare risorse naturali e a proteggere l'ambiente e la salute umana.

Symbolen innebär att enligt lokal lagstiftning ska produkten och/eller dess batteri kastas separat från hushållsavfallet. När den här produkten når

slutet av sin livslängd ska du ta den till en återvinningsstation. Vid tiden för kasseringen bidrar du till en bättre miljö och mänsklig hälsa genom att

göra dig av med den på ett återvinningsställe.

台灣

以下訊息僅適用於產品銷售至台灣地區

• 這是甲類的資訊產品，在居住的環境中使用時，可能會造成射頻干擾，在這種情況下，使用者會被要求採取某些適當的對策。

安全警告

為了您的安全，請先閱讀以下警告及指示 :

• 請勿將此產品接近水、火焰或放置在高溫的環境。

• 避免設備接觸

任何液體 - 切勿讓設備接觸水、雨水、高濕度、污水腐蝕性的液體或其他水份。

灰塵及污物 - 切勿接觸灰塵、污物、沙土、食物或其他不合適的材料。

• 雷雨天氣時，不要安裝，使用或維修此設備。有遭受電擊的風險。

• 切勿重摔或撞擊設備，並勿使用不正確的電源變壓器。

• 若接上不正確的電源變壓器會有爆炸的風險。。

• 請勿隨意更換產品內的電池。

• 如果更換不正確之電池型式，會有爆炸的風險，請依製造商說明書處理使用過之電池。

• 請將廢電池丟棄在適當的電器或電子設備回收處。

• 請勿將設備解體。

• 請勿阻礙設備的散熱孔，空氣對流不足將會造成設備損害。

• 請插在正確的電壓供給插座 ( 如 : 北美 / 台灣電壓 110V AC，歐洲是 230V AC)。

• 假若電源變壓器或電源變壓器的纜線損壞，請從插座拔除，若您還繼續插電使用，會有觸電死亡的風險。

• 請勿試圖修理電源變壓器或電源變壓器的纜線，若有毀損，請直接聯絡您購買的店家，購買一個新的電源變壓器。

• 請勿將此設備安裝於室外，此設備僅適合放置於室內。

• 請勿隨一般垃圾丟棄。

• 請參閱產品背貼上的設備額定功率。

Appendix D Legal Information

GS2220 Series User’s Guide

447

• 請參考產品型錄或是彩盒上的作業溫度。

• 設備必須接地，接地導線不允許被破壞或沒有適當安裝接地導線，如果不確定接地方式是否符合要求可聯繫相應的電氣檢驗機構檢驗。

• 如果您提供的系統中有提供熱插拔電源，連接或斷開電源請遵循以下指導原則

- 先連接電源線至設備連，再連接電源。

- 先斷開電源再拔除連接至設備的電源線。

- 如果系統有多個電源，需拔除所有連接至電源的電源線再關閉設備電源。

• 產品沒有斷電裝置或者採用電源線的插頭視為斷電裝置的一部分，以下警語將適用 :

- 對永久連接之設備，在設備外部須安裝可觸及之斷電裝置；

- 對插接式之設備，插座必須接近安裝之地點而且是易於觸及的。

About the Symbols

Various symbols are used in this product to ensure correct usage, to prevent danger to the user and others, and to prevent property damage.

The meaning of these symbols are described below. It is important that you read these descriptions thoroughly and fully understand the

contents.

Explanation of the Symbols

Viewing Certifications

Go to http://www.zyxel.com to view this product’s documentation and certifications.

Zyxel Limited Warranty

Zyxel warrants to the original end user (purchaser) that this product is free from any defects in material or workmanship for a specific period (the

Warranty Period) from the date of purchase. The Warranty Period varies by region. Check with your vendor and/or the authorized Zyxel local

distributor for details about the Warranty Period of this product. During the warranty period, and upon proof of purchase, should the product

have indications of failure due to faulty workmanship and/or materials, Zyxel will, at its discretion, repair or replace the defective products or

components without charge for either parts or labor, and to whatever extent it shall deem necessary to restore the product or components to

proper operating condition. Any replacement will consist of a new or re-manufactured functionally equivalent product of equal or higher value,

and will be solely at the discretion of Zyxel. This warranty shall not apply if the product has been modified, misused, tampered with, damaged by

an act of God, or subjected to abnormal working conditions.

Note

Repair or replacement, as provided under this warranty, is the exclusive remedy of the purchaser. This warranty is in lieu of all other warranties,

express or implied, including any implied warranty of merchantability or fitness for a particular use or purpose. Zyxel shall in no event be held

liable for indirect or consequential damages of any kind to the purchaser.

To obtain the services of this warranty, contact your vendor. You may also refer to the warranty policy for the region in which you bought the

device at http://www.zyxel.com/web/support_warranty_info.php.

Registration

Register your product online to receive e-mail notices of firmware upgrades and information at www.zyxel.com for global products, or at

www.us.zyxel.com for North American products.

Trademarks

ZyNOS (Zyxel Network Operating System) and ZON (Zyxel One Network)are registered trademarks of Zyxel Communications, Inc. Other

trademarks mentioned in this publication are used for identification purposes only and may be properties of their respective owners.

SYMBOL EXPLANATION

Alternating current (AC):

AC is an electric current in which the flow of electric charge periodically reverses direction.

Direct current (DC):

DC if the unidirectional flow or movement of electric charge carriers.

Earth; ground:

A wiring terminal intended for connection of a Protective Earthing Conductor.

Class II equipment:

The method of protection against electric shock in the case of class II equipment is either double insulation

or reinforced insulation.

Index

GS2220 Series User’s Guide

448

Index

Numbers

802.1P priority 90

AAA 224

accounting 224, 225

authentication 224, 225

authorization 224, 225

external server 224

RADIUS 224

AAA (Authentication, Authorization and Accounting) 225

access control

limitations 372

remote management 380

service port 380

SNMP 382

accounting

setup 229

Address Resolution Protocol (ARP) 354, 407, 410, 411

administrator password 379

aging time 85

anti-arpscan 317

blocked hosts 318

host threshold 320

status 318

trusted hosts 319

applications

bridging 26

IEEE 802.1Q VLAN 27

switched workgroup 27

ARP

how it works 354

learning mode 354

overview 354

setup 356

ARP (Address Resolution Protocol) 407

ARP inspection 237, 265

and MAC filter 265

Index

GS2220 Series User’s Guide

449

configuring 266

syslog messages 266

trusted ports 266

ARP scan 317

ARP-Reply 354

ARP-Request 355

authentication

setup 229

authentication, authorization and accounting 224

Authentication, Authorization and Accounting, see AAA 225

authorization

privilege levels 231

setup 229

automatic VLAN registration 111

bandwidth control 159

egress rate 160

ingress rate 160

setup 159

basic settings 80

basic setup tutorial 63

binding 237

binding table 237

building 237

BPDU 322

BPDU (Bridge Protocol Data Units) 322

BPDU guard 322

and Errdisable Recovery 322

port status 322

BPDUs 139

Bridge Protocol Data Units 322

Bridge Protocol Data Units (BPDUs) 139

broadcast storm control 161

cable diagnostics 393

CDP 275

certifications

viewing 447

CFI 111

Index

GS2220 Series User’s Guide

450

CFI (Canonical Format Indicator) 111

changing the password 55

Cisco Discovery Protocol, see CDP

CIST 158

Class of Service (CoS) 339

classifier 185

and QoS 185

editing 190

example 192

logging 191

match order 191

overview 185

setup 186, 190

status 185

viewing 190

cloning a port See port cloning

cluster management 398

and switch passwords 401

cluster manager 398, 400

cluster member 398, 401

cluster member firmware upgrade 402

network example 398

setup 400

specification 398

status 399

switch models 398

VID 401

web configurator 402

cluster manager 398

cluster member 398

command interface 29

Common and Internal Spanning Tree, See CIST 158

configuration 336

change running config 361

configuration file 57

restore 57, 364

saving 360

configuration, saving 56

console port

settings 39

contact information 427

copying port settings, See port cloning

CPU management port 128

CPU protection 285

current date 83

Index

GS2220 Series User’s Guide

451

current time 83

customer support 427

daylight saving time 84

DHCP

configuration options 343

Dynamic Host Configuration Protocol 343

modes 343

Relay Agent Information format 345

setup 344

DHCP relay option 82 264

DHCP snooping 63, 237, 263

configuring 264

DHCP relay option 82 264

trusted ports 263

untrusted ports 263

DHCP snooping database 264

DHCPv4

global relay 347

global relay example 349

Option 82 345

option 82 profiles 346

Relay Agent Information 345

DHCPv4 relay 344

DHCPv6 relay 352

interface-ID 352

remote-ID 352

diagnostics 392

Ethernet port test 393

ping 393

Differentiated Service (DiffServ) 339

DiffServ 339

activate 340

DS field 339

DSCP 339

network example 339

PHB 339

disclaimer 444

DNS 107

DNS (Domain Name System) 107

Domain Name System 107

DS (Differentiated Services) 339

DSCP

Index

GS2220 Series User’s Guide

452

service level 339

what it does 339

DSCP (DiffServ Code Point) 339

dual firmware images 362

dynamic link aggregation 165

egress rate, and bandwidth control 160

errdisable status 288

error disable 285

control packets 287

CPU protection 288

detect 289

recovery 290

status 286

error-disable recovery 285

Ethernet broadcast address 354, 407

Ethernet MAC 81

Ethernet OAM 325

Ethernet port test 393

Ethernet ports

default settings 38

external authentication server 225

FCC interference statement 444

file transfer using FTP

command example 370

filename convention, configuration

configuration

file names 370

filtering 136

rules 136

filtering database, MAC table 404

firmware 81

upgrade 362, 402

flow control

back pressure 90

IEEE802.3x 90

forwarding

delay 148

Index

GS2220 Series User’s Guide

453

frames

tagged 119

untagged 119

front panel 35

FTP 29, 369

file transfer procedure 370

restrictions over WAN 371

GARP 111

GARP (Generic Attribute Registration Protocol) 111

GARP timer 85, 112

general setup 82

getting help 58

GMT (Greenwich Mean Time) 84

gratuitous ARP 355

green Ethernet 293

and uplink port 293

auto power down 293

EEE 293

short reach 293

GVRP 112, 118, 119

and port assignment 119

GVRP (GARP VLAN Registration Protocol) 112

hardware installation 30

mounting 32

hardware monitor 81

hardware overview 35

hello time 147

HTTPS 386

certificates 386

implementation 386

public keys, private keys 386

HTTPS example 387

IEEE 802.1x

Index

GS2220 Series User’s Guide

454

activate 174

port authentication 172

reauthentication 176

IEEE 802.3az 293

IGMP filtering

profile 210

IGMP leave timeout

fast 208

mormal 208

IGMP snooping 202

MVR 203

IGMP throttling 208

ingress rate, and bandwidth control 160

initial setup 59

Installation

Rack-mounting 31

installation

freestanding 30

precautions 31

installation scenarios 30

Internet Protocol version 6, see IPv6

introduction 21

IP address 87

IP setup 86

IP source guard 237

ARP inspection 237, 265

DHCP snooping 237, 263

static bindings 237

IP subnet mask 87

IPv6 28, 436

addressing 436

EUI-64 438

global address 436

interface ID 438

link-local address 436

Neighbor Discovery Protocol 28, 436

neighbor table 413

ping 28, 436

prefix 436

prefix length 436

stateless autoconfiguration 438

unspecified address 437

IPv6 interface 96

DHCPv6 client 106

enable 101

global address 103

link-local address 102

Index

GS2220 Series User’s Guide

455

neighbor discovery 103

neighbor table 104

stateless autoconfiguration 101

IPv6 multicast

211

status 211

IPv6 neighbor table 413

L2PT 273

access port 274

CDP 273

configuration 274

encapsulation 273

example 273

LACP 274

MAC address 273, 275

mode 274

overview 273

PAgP 274

point to point 274

STP 273

tunnel port 274

UDLD 274

VTP 273

LACP 165, 276

system priority 169

timeout 170

Layer 2 protocol tunneling, see L2PT

LEDs 41

link aggregation 165

dynamic 165

ID information 166

setup 167

traffic distribution algorithm 167

traffic distribution type 168

trunk group 165

Link Aggregation Control Protocol (LACP) 165

Link Layer Discovery Protocol 295

LLDP 295

Basic TLV 310

global settings 309

local port status 299

organization-specific TLV 311

status of remote device 303

Index

GS2220 Series User’s Guide

456

TLV 295

LLDP (Link Layer Discovery Protocol) 295

LLDP-MED 296

classes of endpoint devices 296

example 296

lockout 56

log message 394

password 55

Administrator 378

non-administrator 378

configuring via web configurator 378

multiple 378

number of 378

loop guard 267

examples 268

port shut down 268

setup 269

vs. STP 267

MAC 81

MAC (Media Access Control) 81

MAC address 81, 407

maximum number per port 182

MAC address learning 85, 182

specify limit 182

MAC filter

and ARP inspection 265

MAC table 404

display criteria 406

how it works 404

sorting criteria 406

transfer type 406

viewing 405

maintanence

firmware 362

restoring configuration 364

maintenance 358

current configuration 359

main screen 359

Index

GS2220 Series User’s Guide

457

Management Information Base (MIB) 382

management IP address 86

managing the device

good habits 29

using FTP. See FTP.

using SNMP. See SNMP.

using Telnet. See command interface.

using the command interface. See command interface.

using the web configurator. See web configurator.

man-in-the-middle attacks 265

maximum transmission unit 409

Mbuf 367

Mbuf (Memory Buffer) 367

Media Access Control 81

Memory Buffer 367

MIB

and SNMP 382

supported MIBs 383

MIB (Management Information Base) 382

mini GBIC ports 36

transceiver installation 36

transceiver removal 37

mirroring ports 163

MLD filtering profile 217

MLD snooping-proxy 212

filtering 216

filtering profile 217

port role 214

VLAN ID 213

monitor port 163

mounting brackets 32

MST Instance, See MSTI 157

MST region 157

MSTI 148, 157

MSTI (Multiple Spanning Tree Instance) 148

MSTP 138, 140

bridge ID 151

configuration digest 152

forwarding delay 148

Hello Time 151

hello time 147

Max Age 148, 151

maximum hops 148

revision level 148

status 150

MTU 409

Index

GS2220 Series User’s Guide

458

MTU (Multi-Tenant Unit) 84

multicast

IGMP throttling 208

IP addresses 201

setup 205

multicast group 210

multicast MAC address 133

Multiple Spanning Tree Protocol, See MSTP 138, 140

Multiple STP 140

Multi-Tenant Unit 84

MVR 203

configuration 218

network example 203

MVR (Multicast VLAN Registration) 203

network management system (NMS) 382

NTP (RFC-1305) 83

OAM 325

details 326

discovery 325

port configuration 325

remote loopback 325

remote-loopback 331

one-time schedule 183

Operations, Administration and Maintenance 325

Option 82 345

PAGP 276

password 55

administrator 379

Path MTU 409

Path MTU Discovery 409

PHB (Per-Hop Behavior) 339

ping, test connection 393

Index

GS2220 Series User’s Guide

459

PoE

PD priority 94

power management mode 94

policy 194

and classifier 194

and DiffServ 194

configuration 194

example 197

overview 194

rules 194

Port Aggregation Protocol, see PAgP

port authentication 172

guest VLAN 176

IEEE802.1x 174

MAC authentication 178

method 174

port cloning 410, 411

advanced settings 410, 411

basic settings 410, 411

port details 416

port mirroring 163

port redundancy 165

port security 181

limit MAC address learning 182

MAC address learning 181

overview 181

setup 181

port setup 88

port status 415

port details 416

port utilization 421

port VLAN ID, see PVID 119

port VLAN trunking 112

port-based VLAN 128

ports

diagnostics 393

mirroring 163

speed/duplex 89

standby 165

power

voltage 82

power module

disconnecting 41

power status 82

PPPoE IA 277

agent sub-options 279

Index

GS2220 Series User’s Guide

460

configuration 279

drop PPPoE packets 281

port state 279

sub-option format 278

tag format 277

trusted ports 279

untrusted ports 279

VLAN 283

PPPoE Intermediate Agent 277

priority level 86

priority queue assignment 86

product registration 447

PVID 111

QoS

and classifier 185

queue weight 199

queuing 198

SPQ 198

WRR 198

queuing method 198, 200

RADIUS 225

advantages 225

and tunnel protocol attribute 232

setup 226

Rapid Spanning Tree Protocol, See RSTP. 138

reboot

load configuration 361

reboot system 361

recurring schedule 183

registration

product 447

remote management 380

service 381

trusted computers 381

resetting 56, 360, 361, 362

to custom default settings 362

to factory default settings 360, 361

restoring configuration 56, 364

Index

GS2220 Series User’s Guide

461

RFC 3164 395

Round Robin Scheduling 198

RSTP 138

configuration 142

status 144

running configuration 360

erase 360

reset 360

save configuration 56, 360

schedule

one-time 183

recurring 183

type 184

Secure Shell See SSH

service access control 380

service port 380

Simple Network Management Protocol, see SNMP

SNMP 29, 382

agent 382

and MIB 382

authentication 377, 378

communities 374

management model 382

manager 382

MIB 383

network components 382

object variables 382

protocol operations 382

security 377, 378

setup 373

traps 374

users 376

version 3 and security 382

versions supported 382

SNMP traps 383

supported 383, 384

Spanning Tree Protocol, See STP. 138

SPQ (Strict Priority Queuing) 198

SSH

encryption methods 386

how it works 385

implementation 386

SSH (Secure Shell) 385

Index

GS2220 Series User’s Guide

462

SSL (Secure Socket Layer) 386

standby ports 165

static bindings 237

static MAC address 131

static MAC forwarding 131

static multicast address 133

static multicast forwarding 133

static route

enable 337

metric 337

static routes 336

static VLAN 116

control 117

tagging 117

status 74

LED 41

MSTP 150

port 415

power 82

RSTP 144

VLAN 114

STP 138, 275

bridge ID 145, 155

bridge priority 143, 154

designated bridge 139

edge port 144, 154

forwarding delay 144

Hello BPDU 139

Hello Time 143, 145, 154, 155

how it works 139

Max Age 143, 145, 154, 155

path cost 139, 144, 154

port priority 144, 154

port role 146, 156

port state 140, 145, 156

root port 139

status 141

terminology 139

vs. loop guard 267

subnet based VLANs 119

switch lockout 56

switch reset 56

switch setup 85

syslog 266, 395

protocol 395

settings 395

setup 395

Index

GS2220 Series User’s Guide

463

severity levels 395

system information 80

system reboot 361

TACACS+ 225

advantages 225

setup 227

tagged VLAN 111

Tech-Support 366

log enhancement 366

temperature indicator 82

time

current 83

Time (RFC-868) 83

time range 183

time server 83

time service protocol 83

format 83

trademarks 447

transceiver

installation 36

removal 37

traps

destination 374

trunk group 165

trunking 165

trusted ports

ARP inspection 266

DHCP snooping 263

PPPoE IA 279

tunnel protocol attribute

and RADIUS 232

tutorials 63

DHCP snooping 63

Type of Service (ToS) 339

UDLD 276

UniDirectional Link Detection, see UDLD

untrusted ports

Index

GS2220 Series User’s Guide

464

ARP inspection 266

DHCP snooping 263

PPPoE IA 279

user profiles 225

Vendor Specific Attribute, See VSA 231

VID 114

number of possible VIDs 111

priority frame 111

VID (VLAN Identifier) 111

Virtual Local Area Network 84

VLAN 84

acceptable frame type 119

automatic registration 111

ID 111

ingress filtering 119

introduction 84, 111

number of VLANs 114

port settings 118

port-based VLAN 128

PVID 119

static VLAN 116

status 114, 115

subnet based 119

tagged 111

terminology 112

trunking 112, 119

type 85, 113

VLAN (Virtual Local Area Network) 84

VLAN ID 88, 111

VLAN mapping 270

activating 271

configuration 271

example 270

priority level 270

tagged 270

traffic flow 270

untagged 270

VLAN ID 270

VLAN terminology 112

VLAN trunking 119

VLAN Trunking Protocol, see VTP

Voice VLAN 123

VSA 231

Index

GS2220 Series User’s Guide

465

VTP 275

warranty 447

note 447

web configurator 28, 43

getting help 58

layout 51

logout 57

navigation panel 52

weight, queuing 199

Weighted Round Robin Scheduling (WRR) 199

WRR (Weighted Round Robin Scheduling) 198

ZON Utility 46

ZULD 332

example 332

probe time 334

status 333

ZULD (Zyxel Unidirectional Link Detection) 332

ZyNOS (ZyXEL Network Operating System) 370

Zyxel Unidirectional Link Detection 332

Zyxel Unidirectional Link Detection (ZULD) 332