Allied Telesis AT-S63 User Manual

AT-S63 Management Software Menus Interface User’s Guide

Section V: VLANs

585

Figure 207 provides an example of how GVRP works.

Figure 207. GVRP Example

Switches #1 and #3 contain the Sales VLAN, but switch #2 does not.
Consequently, the end nodes of the two parts of the Sales VLANs are
unable to communicate with each other.

Without GVRP, you would need to configure switch #2 by creating the
Sales VLAN on the switch and adding ports 2 and 3 as members of the
VLAN. If you happen to have a large network with a large number of
VLANs, such manual configurations can be cumbersome and time
consuming.

GVRP can make the configurations for you. Here is how GVRP would
resolve the problem in the example.

1. Port 1 on switch #1 sends a PDU to port 2 on switch #2, containing the

VIDs of all the VLANs on the switch. One of the VIDs in the PDU would
be that of the Sales VLAN, VID 11.

2. Switch #2 examines the PDU it receives on port 2 and notes that it

does not have a VLAN with a VID 11. So it creates the VLAN as a
dynamic GVRP VLAN and assigns it a VID 11 and the name
GVRP_VLAN_11. (The name of a dynamic GVRP VLAN has the prefix
“GVRP_VLAN_”, followed by the VID number.) The switch then adds
port 2, the port that received the PDU, as a tagged member of the
VLAN.

3. Switch #2 sends a PDU out port 3 containing all of the VIDs of the

VLANs on the switch, including the new GVRP_VLAN_11 with its VID
of 11. (Note that port 3 is not yet a member of the VLAN. Ports are
added to VLANs when they receive, not send a PDU.)

4. Switch #3 receives the PDU on port 4 and, after examining it, notes

that one of the VLANs on switch #2 has the VID 11, which matches the
VID of an already existing VLAN on the switch. So it does not create
the VLAN because it already exists. It then determines whether the

FAULT

RPS

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GBIC

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GBIC

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CLASS 1

LASER PRODUCT

STATUS

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PORT

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11

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AT-9424T/GB

Gigabit Ethernet Switch

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L/A

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HDX / COL

FDX

10/100 LINK / ACT

PORT ACTIVITY

L/A

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FAULT

RPS

MASTER

POWER

GBIC

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LASER PRODUCT

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PORT

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PORT ACTIVITY

L/A

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FAULT

RPS

MASTER

POWER

GBIC

23

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LASER PRODUCT

STATUS

TERMINAL

PORT

1

3

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11

2

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Gigabit Ethernet Switch

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L/A

1000 LINK / ACT

GBIC

Port 1

Port 2

Port 4

Port 3

Switch #3
Static VLAN
Sales VID=11

Switch #1
Static VLAN
Sales VID=11

Switch #2