Metro Ethernet UNI Standards Update

1. Metro Ethernet UNI Standards Update Gary Southwell VP of Product Marketing Internet Photonics MEF Marketing Collateral co-chair gsouthwell@internetphotonics.com

2. Agenda UNI – Purpose UNI – Overview of Requirements UNI – Architectural Fit UNI – Enabled services Status & next steps/activities

3. ServicesMetro Ethernet Forum Network ImplementationIEEE 802.1 and IETF PPVPN OA&MMetro Ethernet Forum Ethernet Services Standardization UNI

4. Metro Ethernet UNI • Purpose • Provides a network subscriber edge demarcation point for a MEN • Requirements Define demarcation for service • connectivity, • signaling, • Provisioning • Fault detection/resolution • Monitoring and management

5. Ethernet Services Model,Phase 1 CustomerEdge (CE) User NetworkInterface(UNI) User NetworkInterface(UNI) CustomerEdge (CE) MetroEthernetNetwork ServiceAttributes A service is what the CE sees (UNI-to-UNI). The technology used inside the MEN is not visible.

6. User Network Interface (UNI) The demarcation point between Service Provider and Subscriber Responsibilities • Dedicated to a single Subscriber • Standard Ethernet (IEEE 802.3 – 2002) • More than 100 million devices available as CE • Examples: • RJ 45 Socket on Service Provider owned Ethernet switch • RJ45 plug on Service Provider owned cable

7. Service Definitions • Ethernet Line Service (E-Line) • Point-to-Point EVC • Any valid set of other service attributes • Ethernet LAN Service (E-LAN) • Multipoint-to-Multipoint EVC • Any valid set of other service attributes • Examples for typical scenarios, e.g., LAN Extension, Internet Access, Headquarters to Branch Offices

8. Point-to-Point Ethernet Virtual Circuits Servers UNI IP Phone IP PBX Metro Ethernet Network CE Data CE 1 or more UNIs Video UNI CE E-Line Service

9. Multipoint-to-Multipoint Ethernet Virtual Circuit Servers IP Phone UNI UNI Data IP PBX CE Metro Ethernet Network CE UNI CE CE UNI E-LAN Service

10. UNI Reference Point • UNI divided into two subsets • UNI-C describes the end customer UNI • UNI-N describes the end customer UNI

11. UNI Reference Model • UNI data plane • defines the means of transporting information across the UNI reference point • UNI control plane • defines the means for the customer and the MEN provider to make use of the UNI data plane • UNI management plane • controls the operation of the UNI data and control plane

12. UNI Data Plane • Ethernet frame flow • IEEE 802.3 frames (only) • Tagging • Allows customer equipment (CE) to send 802.1q tagged frames across the UNI for segmentation purposes • Traffic Mgmt • Binds the subscriber transmissions to traffic policies as set by an SLA

13. UNI Control Plane • a static service discovery function that allows no or auto-configuration of the CE (PVC mode) • a dynamic connection setup function that allows dynamic establishment of Ethernet services (SVC mode).

14. UNI Management Plane • QOS Mgmt • Allows provisioning of service attributes thought traffic identifiers • Protection & restoration • Allows links from the (CE) into the MEN to be protected by various means • OAM • Connectivity verification, performance monitoring and SLA stats gathering

15. Ethernet Services Control Function • A UNI-N - Demarc Component (ESCF) • ESCF • SP’s network equipment that provides the functional element required to meter, police and shape the flow to and from the SP’s Demarc • 1st point where policy is enforced in the MEN

16. Ethernet Virtual Connection(EVC) • Association of two or more UNIs • Frames can only be exchanged among the associated UNIs • A frame sent into the SP network via a particular UNI MUST NOT be delivered out of the SP network via that UNI

17. EVCS & Closed User Groups • EVCS can form closed user groups (CUGS) • Marked by VLANs or other means of identification • Frames can only be exchanged among the associated UNIs • Note UNIs can support multiple CUGs

18. Point-to-Point EVC Exactly two UNIs are associated.

19. Multipoint-to-Multipoint EVC • Two* or more UNIs are associated • A flooded, broadcast or multicast ingress frame is typically replicated and delivered to all of the other UNIs * A MP2MP EVC with two UNIs is different than a P2P EVC since additional UNIs can be added at any time.

20. Service Multiplexing B ServiceMultiplexing A C EVC1 EVC2 EVC3 D • Multiple EVCs at a UNI • Efficient use of CE port • Multiple revenue streams per SP UNI

21. UNI Service Model

22. UNI Traffic and Performance Control examples • Ingress policing based on a two rate, three color Token Bucket model • Similar to the CIR, Bc, Be of Frame Relay • Allows Subscriber to buy bandwidth with high granularity • Performance parameters, e.g., Frame Delay, Frame Loss, Availability • Definitions for the basis of a Service Level Specification in a Service Level Agreement

23. UNI EVC Control Example • Customer Equipment configuration control

24. UNI Modes PVC • Start with Static UNI-C config…100% of installed base compatible • No chgs to Customer device config. • E.g. assigned VLANs) • Introduce auto provisioning • DCE Access to CE via LMI to learn what it is connected to and configures CE automatically • E.g. configured VLANs

25. UNI Modes SVC (Full Definition still pending) • UNI-C requests via signaling what EVCs it desires connectivity with • Negotiates the service parameters if applicable • Provides for backward comaptibility

26. Ethernet OA&M CE CE OA&M OA&M OA&M • Availability • Status Monitoring • Scalability • Extensibility • Security • Tunnel and Transport Independence • Layer 3 Independence

27. Status • Ethernet UNI 1.0 in draft • UNI 1 Interoperability Agreement work in process • UNI 2 - work in process

28. Thank You