Deployment Guide

NOTE: For more information on how to congure FRRP, see FRRP

Conguration

NOTE: For more information on conguring VLT between 2 devices, see Conguring

VLT

Example Scenario

Following example scenario describes an Active-Active FRRP ring topology where the ring is blocked on a per VLAN or VLAN group basis

allowing active-active FRRP ring for dierent set of VLANs.

In this scenario, an FRRP ring named R1 is congured with VLT Node1 acting as the Master node and VLT Node2 as the transit node.

Simillary, an FRRP ring named R2 is congured with VLT Node2 as the master node and VLT node1 as the trasit node.

In the FRRP ring R1, the primary interface for VLT Node1 is the VLTi. P1 is the secondary interface, which is an orphan port that is

participating in the FRRP ring topology. V1 is the control VLAN through which the RFHs are exchanged indicating the health of the nodes

and the FRRP ring itself. In addition to the control VLAN, multiple member VLANS are congured (for example, M1 through M10) that carry

the data trac across the FRRP rings. The secondary port P1 is tagged to the control VLAN (V1). VLTi is implicitly tagged to the member

VLANs when these VLANs are congured in the VLT peer.

As a result of the VLT Node1 conguration, the FRRP ring R1 becomes active by blocking the secondary interface P1 for the member

VLANs (M1 to M10).

VLT Node2 is the transit node. The primary interface for VLT Node2 is VLTi. P2 is the secondary interface, which is one of the orphan port

participating in the FRRP ring. V1 is the control VLAN through which the RFHs are exchanged. In addition to the control VLAN, multiple

member VLANS are congured (for example, M1 to M10) that carry the data trac across the FRRP rings. The secondary port P2 is

tagged to the control VLAN (V1). VLTi is implicitly tagged to the member VLANs when these VLANs are congured in the VLT peer.

As a result of the VLT Node2 conguration on R2, the primary interface VLTi and the secondary interface P1 act as forwarding ports for the

member VLANs (M1 to M10).

In the FRRP ring R2, the primary interface for VLT Node1 (transit node) is the VLTi. P1 is the secondary interface, which is an orphan port

that is participating in the FRRP ring topology. V1 is the control VLAN through which the RFHs are exchanged indicating the health of the

nodes and the FRRP ring itself. In addition to the control VLAN, multiple member VLANS are congured (for example, M11 through Mn)

that carry the data trac across the FRRP rings. The secondary port P1 is tagged to the control VLAN (V1). VLTi is implicitly tagged to the

member VLANs when these VLANs are congured in the VLT peer.

As a result of the VLT Node1 conguration on R2, the FRRP ring R2 becomes active. The primary interface VLTi and the secondary

interface P1 act as forwarding ports for the member VLANs (M11 to Mn).

VLT Node2 is the master node. The primary interface for VLT Node2 is VLTi. P2 is the secondary interface, which is one of the orphan port

participating in the FRRP ring. V1 is the control VLAN through which the RFHs are exchanged. In addition to the control VLAN, multiple

member VLANS are congured (for example, M1 to M10) that carry the data trac across the FRRP rings. The secondary port P2 is

tagged to the control VLAN (V1). VLTi is implicitly tagged to the member VLANs when these VLANs are congured in the VLT peer.

As a result of the VLT Node2 conguration on R2, the secondary interface P2 is blocked for the member VLANs (M11 to Mn).

Following gure illustrated the FRRP Ring R1 topology:

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Force10 Resilient Ring Protocol (FRRP)