Metro Ethernet (paperback) at Dominant Systems Book Store

The definitive guide to Enterprise and Carrier Metro Ethernet applications

Discover the latest developments in metro networking, Ethernet, and MPLS services and what they can do for your organization
Learn from the easy-to-read format that enables networking professionals of all levels to understand the concepts
Gain from the experience of industry innovator and best-selling Cisco Press author, Sam Halabi, author of Internet Routing Architectures

Metro networks will emerge as the next area of growth for the networking industry and will represent a major shift in how data services are offered to businesses and residential customers. The metro has always been a challenging environment for delivering data services because it has been built to handle the stringent reliability and availability needs for voice. Carriers will have to go through fundamental shifts to equip the metro for next-generation data services demanded by enterprise customers and consumers. This is not only a technology shift, but also a shift in the operational and business model that will allow the incumbent carriers to transform the metro to offer enhanced data services.

Metro Ethernet from Cisco Press looks at the deployment of metro data services from a holistic view. It describes the current metro, which is based on TDM technology, and discusses the drivers and challenges carriers will face in transforming the metro to address data services.

Metro Ethernet discusses the adoption of metro Ethernet services and how that has led carriers to the delivery of metro data services. With a changing mix of transport technologies, the book then examines current and emerging trends, and delves into the role of virtual private networks (VPN), virtual private local area networks (VLAN), virtual private LAN services (VPLS), traffic engineering, and MPLS and Generalized MPLS (GMPLS).

Customer Reviews & Comments
Sam Halabi's book is described on the cover as "the definitive guide to enterprise and carrier metro Ethernet applications". As you would expect from the author of the justly-celebrated "Internet Routing Architectures", Halabi does a superb job. Chapter 1 reviews traditional TDM ways of getting to the customer. With traditional SDH/SONET-based transmission, carriers pay a high price in operational complexity, cost and provisioning delay. Ethernet's advantages include fast provisioning, fine-grained bandwidth granularity (inherent in packet technologies) and a scalability from kbps to Gbps. The customer also expects a lower cost service, although carrier pricing remains volatile, partially from fear of cannibalising their existing connectivity revenues. Chapter 2 looks at metro Ethernet technologies. Carriers with already deployed SONET/SDH networks naturally consider how to use them efficiently to carry Ethernet. The problem of mapping continuously-scalable packet flows into the lumpy SONET/SDH bandwidth hierarchy is well-described. Generic Framing Procedure (GFP) is becoming an increasingly popular adaptation layer between Ethernet (and other packet protocols such as PPP, Fiber Channel, FICON/ESCON) and SDH/SONET, implemented via the evolution of SONET/SDH devices into Multi-Service Provisioning Platforms (MSPPs). The bandwidth mismatches are addressed via Virtual Concatenation (VCAT) and Link Capacity Adjustment Scheme (LCAS). Ethernet-over-SONET/SDH as just described is a pure transport mechanism. To create an Ethernet analogue of add-drop multiplexing and to support traffic aggregation, L2 switching functionality needs to be added to the basic SDH/SONET box. (This is a well-worn path for transmission vendors - the same model was proposed for ATM). Different customers' Ethernet streams need to be identifiable, and carrier VLAN tagging is a possibility, although MPLS provides a more scalable solution, discussed later. In L2 switching in ring topologies, bandwidth fairness and efficient protection switching is difficult to achieve. The new "Resilient Packet Ring" (RPR) MAC protocol was developed to address these issues, and RPR can be run over GFP, and therefore supported in SONET/SDH devices which understand the RPR protocol. Of course, one can dispense with SONET/SDH equipment altogether (especially if you are a new operator and never installed it). Halabi briefly touches on the deployment and management of Gigabit Ethernet switches with direct interconnect. Chapter 3 is devoted to metro Ethernet services. After a brisk tutorial on L2 switching, MAC learning, flooding, broadcast/multicast, VLANs and spanning tree protocol, Halabi gets down to the services. The Metro Ethernet Forum has defined two Ethernet service types: Ethernet Line Service (ELS) and Ethernet LAN service (E-LAN). Point-to-point vs. multipoint-to-multipoint, or transport vs. transport-and-switching if you prefer. ELS issues include traffic and performance management, class-of-service, VLAN support. Additional issues for E-LAN services focus on mechanisms for customer-separation, address-management and scalability. Halabi identifies a number of issues along the way: with the VLAN tag length restricting operators to 4,096 customer-id values, operational services cannot scale; Ethernet does not have the kind of embedded OA&M facilities which allow carrier services such as SONET/SDH to be monitored and provisioned; the spanning tree protocol for loop-prevention does not scale and is inefficient; VPN configuration is hard to scale. Chapter 4: "hybrid L2 and L3 IP/MPLS networks" unveils the solution. In a nutshell it is to adapt Ethernet to MPLS at the network edge, and use the power of BGP/MPLS VPN technology to scale the service. Halabi starts by reviewing standard L3 VPNs, both IP tunnels (GRE, not IPsec) and BGP/MPLS rfc 2547. He then notes that Ethernet can be carried over MPLS via the IETF Pseudowire standard - this is fine for Ethernet Line Services. An E-LAN service such as Virtual Private LAN Service requires more work from the CE/PE devices, however. Specifically, the CEs think they are talking to an Ethernet switch on their link to the PE. The PE needs the additional functionality of a VLAN switch, and maps a specific MPLS label to each VLAN on a per-customer basis. This "broadcast domain" identification inner label is then augmented by an outer traffic-engineering label to forward traffic to the correct destination PE across the Service Provider network. Halabi describes in detail the mechanisms, which are similar to rfc 2547 VPNs at L3. In practice there are still scaling issues, and the concept of "Decoupled Transparent LAN Service" is introduced. This creates an additional customer-premises PE which specialises in L2 MAC address management and customer segmentation, while the network POP PE can specialise in L3 MPLS tunnel and connectivity management. Given the detailed technical treatment, this is one of the harder chapters in the book. However, this is the last chapter actually devoted to Ethernet. With Chapter 5, we enter part II of the book, which is more focused on traffic engineering and GMPLS. This chapter is a fast review of MPLS for traffic engineering of IP networks. Chapter 6 extends this discussion to cover the details of RSVP-TE for LSP establishment, specifically for fast-reroute. In Chapter 7 and the final Chapter 8, we see how MPLS (specifically GMPLS) can be used as a generalised control plane for virtual circuit management in the SONET/SDH and the optical layers. The Internet is awash with white papers on all aspects of metro Ethernet. This book was published, by Cisco Press, in September 2003 so it's hot off the press. But sections still appear to be slightly dated in what is an incredibly fast-moving area. Why buy it? Because Halabi knows what he's talking about, and gets down into the detail of how everything works with great intellectual clarity. Although it can be hard to see the wood from the trees in this book, it is the ideal "in one place" reference for both services and technologies for carrier Ethernet. I consider chapters 5-8 as an MPLS bonus, as they actually have nothing specifically to do with carrier Ethernet.

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