Ethernet Ring Protection (ERP) has recently emerged to provide protection switching for Ethernet ring topologies with sub-50 ms failover capabilities. ERP's promise to provide protection in mesh packet transport networks positions Ethernet as a prominent competitor to conventional SONET/SDH and as the technology of choice for carrier networks. Higher service availability, however, in ERP has been challenged by the issue of network partitioning and contention for shared capacity caused by concurrent failures. In this paper, we show that in a network designed to withstand single-link failure, the service availability, in the presence of double link failures, depends on the designed ERP scheme, i.e., the RPL placement as well as the selection of ring hierarchy. Therefore, we present a study for characterizing service outages and propose a design method which strikes a balance between capacity requirement and service availability (i.e., the number of service outages resulting from concurrent failures). We observe that through effective design, remarkable reduction in service outages is obtained at a modest increase in capacity deployment.
Ethernet Ring Protection (ERP) switching has emerged to provide sub-50 ms of restoration times, allowing Ethernet technologies to expand beyond enterprises to next generation metro and backbone networks, providing much needed services to interconnect for instance dispersed and high-bandwidth data centers. This paper considers the problem of efficiently designing and planning an Ethernet-based metro network with ERP protection method. While previous recent work has addressed such design problem, none has considered the capabilities of exploiting multiple ERP instances, leaving behind some advantages that network providers could tap into to provide their customers with desirable quality of service support. Resource planning in ERPbased Ethernet network is, however, a complex problem due to the challenges associated with the logical link block selection as well as ring hierarchy selection. ERP instances add, however, another dimension of combinatorial complexity, making the design problem completely intractable. To address this issue, we resort to large scale optimization tools and present a novel primal-dual decomposition of the original problem using column generation. We show that our method is very scalable and obtain several design insights on various representative network instances.Index Terms-Ethernet ring protection, network design, next generation metro networks, VLAN assignment.
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