Resilient Ethernet Protocol

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Resilient Ethernet Protocol (REP) is a network protocol developed by Cisco Systems as a alternative to the Rapid Spanning Tree Protocol (STP).^[1] Designed to enhance network reliability, REP mitigates the formation of loops, expedites recovery from link failures, and optimizes convergence times. It achieves this by managing a collection of ports that form a REP segment, ensuring the absence of bridging loops within that segment and facilitating rapid response to any interruptions in connectivity.

A REP segment is essentially a sequence of interconnected ports that share a common segment identifier. Each segment is composed of regular segment ports and a pair of edge ports configured by the user.

Limitations are placed on the configuration:

• A single switch is restricted to having at most two ports in the same segment
• REP is supported only on Trunk ports.

REP was initially designed to operate with Fast Ethernet (FE 10/100) interfaces, where it boasts a rapid link down detection time of approximately 10 milliseconds (ms) and a network convergence time around 50 ms. However, the performance of REP varies when deployed over different media types. For Fiber Gigabit Ethernet (GE) ports, the link down detection time remains at an expedient 10 ms, similar to that of Fast Ethernet ports. Conversely, when REP is implemented on Gigabit Ethernet copper interfaces, the detection and recovery times for link losses are notably longer, ranging between 750 ms and 350 ms.

Under normal conditions, where all ports in a segment are functional, one port per VLAN, known as the Alternate (ALT) port, is placed in a blocked state.

When a port becomes non-operational due to a link failure, all remaining ports actively forward traffic across all VLANs to maintain network connectivity.

In the event of a link failure, the protocol swiftly unblocks alternate ports to restore connectivity. Upon recovery of the failed link, the protocol selects a logically blocked port for each VLAN, ensuring minimal network disruption.

In scenarios where REP segments are used within access ring topologies, it is possible to encounter neighboring switches that do not support REP. For such cases, ports facing non-REP switches can be configured as edge no-neighbor ports. These ports have the capability to issue Spanning Tree Protocol Topology Change Notifications (STP TCNs) towards an upstream aggregation switch, thereby maintaining network resilience and performance.

• Huynh, Minh; Goose, Stuart; Mohapatra, Prasant (15 January 2010). "Resilience technologies in Ethernet". Computer Networks (journal). 54 (1): 57–58.