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Supporting Ethernet in OBS networks

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Title: Supporting Ethernet in OBS networks


1
Supporting Ethernet in OBS networks
  • Sami Sheeshia and Chunming Qiao
  • Department of computer science and
    engineering
  • State University of New York at Buffalo
  • Jeffrey U.J.Liu
  • Computer and Communications Research Lab
  • Industrial Technology Research Institute,
    Taiwan
  • 2002 Journal of Optical Computing

2
Overview
  • Abstract
  • Introduction
  • - various standards to enhance Ethernet
  • 10GbE over SONET
  • - disadvantages and quantifying its
    inefficiencies
  • Ethernet over OBS
  • - presenting a viable alterative which
    avoids the
    shortcomings of SONET.
  • Ethernet over OBS specific integration issues-
  • - such as OBS burst size
  • - Multiprotocol Label Switching (MPLS) issues

3
Abstract
  • The paper introduces the likely role that OBS
    will play in the development of 10-Gbit Ethernet
    MAN.
  • SONET (Synchronous optical networking) is being
    proposed for the same but its synchronous
    time-division multiplexing (TDM) is inefficient
    for transporting bursty traffic of the Ethernet.
  • The author claims that OBS provides a better
    sharing of network resources and when coupled
    with generalized multiprotocol label switching
    (GMPLS) provides a robust Ethernet service.

4
Introduction
  • Recently network providers face new challenges at
    the MAN level due to the increased user
    requirements.
  • Tremendous pressure to support broadband access
    and high speed WAN at low cost.
  • So the above factors demands a flexible, proven
    MAN architecture combined with multi-vendor
    compatible implementations.
  • 10GbE promises to play an important role,
    offering good speed, end-to-end protocol
    consistency for providers and users in a cost
    effective manner.
  • 10GbE can operate over long link spans(40 km) and
    other transport layers such as SONET and DWDM.

5
IntroSONET
  • Historically, wide-area connectivity is been
    provided by SONET which were built to carry voice
    traffic.
  • But it is not optimized for the bursty nature of
    the present time data traffic and is not able to
    scale itself to support the rapid growth of
    internet in a cost-effective manner (requires
    ADMs, hubs etc).
  • Gigabit Ethernet has been popular in LAN and the
    MAN , however, Ethernet by itself cannot be
    considered to be a carrier class protocol as it
    does not provide what SONET guarantees.
  • Standards such as Ethernet over WDM, resilient
    packet ring (RPR), packet over SONET (PoS) have
    been developed with carrier-grade qualities.

6
Intro..1.Ethernet over WDM
  • This provides a long haul connectivity(40 km)
    between two Ethernet switches.
  • Point-point connections are done manually or via
    multiprotocol lambda switching.
  • Disadvantage
  • Total number of circuits that can be provisioned
    are limited.
  • No traffic grooming or aggregation can be done.

7
Intro2. Resilient packet ring (RPR)
  • Combines the advantages of Ethernet and SONET to
    give traditional carrier class features.
  • Has good MAC switching capabilities providing
    core fiber and ring operation.
  • Controlled bandwidth allocation, 50-ms service
    restoration, bounded delay and jitters etc.
  • Though RPR in conjunction with SONET and Ethernet
    can provide highly efficient MAN, carriers have
    opted to improve SONET transport instead.

8
Intro3.Packet over SONET (PoS)
  • PoS is a communication protocol for transmitting
    packets over SONET.
  • PoS supports the sending of IP packets over WAN.
  • Disadvantage
  • It aggregates and encapsulates IP datagrams in
    Point-to-Point protocol (PPP) without any
    differentiation among different packet flows.
  • So, lacks multicast and QoS capabilities.

9
IntroNext-generation SONET
  • Provides better bandwidth granularity than SONET
    and POS.
  • Virtual Concatenation (VC) technique allows a
    better match between Ethernet data rates and
    SONET line rate improving circuit use.
  • GFP is proposed to adapt multiservices to the
    SONET by a uniform mapping of Ethernet frames and
    client signals.
  • LCAS provides bandwidth-on-demand capabilities.
  • Disadvantage
  • Does not address issues associated with using
    circuit-switching technology for data traffic.

10
A new proposal
  • Since the standards mentioned either lack
    end-to-end optical transparency or do not offer
    efficient use of core resources, OBS technology
    is taken advantage of to transmit Ethernet frames
    over WDM links.
  • The author explains this provides a scalable and
    data optimized alternative to SONET-based
    connectivity.

11
Ethernet over SONET(EoS)
  • SONET was designed primarily for voice
    applications and is based on circuit oriented
    technology.
  • Dual ring and equipment topology enables SONET to
    implement fast protection mechanisms.
  • 10GbE physical layer is compatible with SONET.
  • ( OC-192 link speed, use of SONET framing).
  • Costly aspects like TDM support, performance and
    management functions have been avoided.

12
Disadvantages of using SONET rings for data
transport
  • Basically SONETs point-to-point design,
    circuit switch applications give rise to its
    limitations.

13
1.Fixed circuits
  • SONET provisions point-to-point circuit between
    ring nodes gt allocated a fixed amount of
    bandwidth.
  • In Fig.1(a) each node in the ring is allocated
    only one quarter of the total bandwidth.
  • Thus a limit is put on the maximum data burst
    traffic rates and increases the queuing delay.
  • To create a logical mesh as in Fig.1(b) requires
    N(N-1) circuits which is time consuming and also
    waste ring bandwidth.

14
2.Muticast Traffic
  • Layer 2 muticast requires each source to allocate
    a separate circuit for each destination.
  • Thus, a mesh has to be created in which separate
    copies of the packet are sent to each
    destination.
  • Obviously, result multiple copies traveling
    around the ring, wasting bandwidth.

15
3.Wasted Protection Bandwidth
  • 50 of ring bandwidth and equipment is reserved
    for protection.
  • SONET does not give the provider the choice of
    when and how much bandwidth to reserve for
    protection.
  • Thus SONET does not provide protection in a
    cost-effective manner.

16
4.Added Overhead
  • SONET overhead (TDM capabilities, physical layer,
    management functions) for STS-192c frames
    resulting from the transportation of 10GbE frames
    over circuits built from SONET links is 3.7.
  • But , at low traffic loads, efficiency worsens as
    large bursts of Ethernet frames are delivered in
    a fraction of SONET time slot.
  • Carrying increasing data traffic over manually
    provisioned circuit-switched networks makes it
    difficult to develop new services thus increasing
    cost.

17
Ethernet-over-SONET Efficiency
  • Due to the burstiness and variable frame size
    of Ethernet traffic there is inefficiency in
    SONET framing.
  • Efficiency of EoS is given by
  • ?EoS ?SONET ?PE
    (1)
  • where ?PE packing efficiency of Ethernet
    frames into SONET payload (SPE).

18
  • g - interarrival gaps
  • r - unused remainder (due to low traffic load,
    size of incoming frame gtgtremainder in time slot)
  • Let the Ethernet frame size be modeled with an
    exponential distribution with parameter ?
    frame/Byte.

19
  • The packing efficiency of the Ethernet frames
    into a SONET Tspe is given by
  • Where M- maximum number of Ethernet frames that
    SPE can hold.
  • B size of the burst.
  • Y Sum of the first frame to the
    last frame.
  • Due to the bursty nature, the time intervals (g)
    gtgtgtTspe
  • Thus as g varies , ?PE becomes proportional to
    the offered load.

(2)
20
Ethernet over OBS
  • MP?S Lack of statistical multiplexing, leads to
    poor flexibility.
  • Recent arrival of optical cross connects (OXC)
    can be used to extend 10GbE over long distances-
    point to point permanent resource reservation-no
    longer shared among different 10GbE.
  • OBS is a new technology that exploits the large
    bandwidths of DWDM by avoiding electronic
    processing of optical packets.
  • No O-E-O conversions in OBS.
  • Burst- basic data block, collection of data
    frames with same destination address and QoS
    parameters.

21
EoS
  • Optical burst is switched by a predetermined path
    by a control packet.
  • Improves backbone efficiency and offers excellent
    scalability.

22
EOS
  • The GMPLS labels are used to identify the
    destination edge switch and are mapped to
    available wavelengths at each OBS switch.
  • 1.Switched paths
  • LOBS do not reserve the resources permanently
  • LOBS are set up dynamically to support required
    QoS and torn down once burst are transmitted.
  • Bandwidth allocated dynamically-burst by burst
    basis.

23
  • 2. Peer-to-Peer Networking
  • GMPLS extends WAN connectivity into the
    MAN-simplifies interface
  • Complex optical UNI interfaces not required.
  • 3. Multicast traffic
  • OBS provides multicast at WDM layer using
    light-splitting techniques-require additional
    hardware-complicate switch controls
  • GMPLS-based multicast provides simplification and
    scalability at no cost.

24
  • 4.Protection and Restoration
  • GMPLS fast reroute mechanism can be used to
    provide protection and restoration by
    automatically rerouting traffic on an alternate
    LOBS.
  • Accomplishes by precomputing number of LOBS paths
    at the same time the primary LOBS paths are
    established.
  • Integrating 10GbE over GMPLS enabled OBS requires
    specific details to burst size and GMPLS
    extensions.

25
Ethernet-over-OBS efficiency
  • OBS efficiency depends on the fraction of time
    the reserved bandwidth along a LOBS path is used
    by the burst .
  • ts- time at which the bandwidth
    reservation starts
  • T- burst time (burst size L/output
    data rate bo)
  • To - offset time

(3)
26
  • End-to-end queuing delay depends whether fixed or
    variable size bursts are used.
  • Fixed size burst allows paths to be set up as the
    burst is being assembled.
  • In the fixed size the data burst encounters no
    edge delay as long as the offset time time
    taken to assemble the burst.
  • In the variable-size, control packet can only be
    sent after entire burst is assembled minimum
    edge delay is To.

27
Ethernet-over-OBS Burst Size
  • For better efficiency, the OBS burst must be
    gtgtTo-ts but not so large to cause significant
    queuing delays.
  • High bandwidth, full-duplex operation requires a
    flow control mechanism 10GbE source and
    destination exchange flow control packets- to
    prevent data loss, throttle frame transmission
    rate.
  • Flow-control packets are typically 64 bytes, not
    assembled into bursts since it affects
    efficiency.
  • Elasticity of OBS burst unlike SONET fixed frame
    slot size allows it to adapt to the bursty nature
    of Ethernet.
  • Ethernet adaptor requires a minimum IFG between 2
    successive frames at 10GbE IFG 9.6ns or 12
    Bytes.
  • IFG provides receiving station time to update
    counters, check CRC of previous frame, mange the
    buffers.

28
  • Two ways to implement IFG-
  • Insert the 12 Byte spacing at the 10GbE receiving
    interface
  • - places new requirements on the processing
    at the destination switch to seek the
    start of each frame.
  • Incorporate the IFG within the burst
  • - maintains the integrity of Ethernet
    transmission at the expense of wasted bandwidth
    within each burst.
  • Since the IFG, preamble, frame check
    sequence (FCS) constitute a large overhead for
    the 1500 Byte Ethernet frame, 9000 Byte frames
    can be used to improve efficiency.
  • For e.g.. 155,520-Byte(SONET slot) carrying
    1500 Byte frames incurs 1 overhead whereas
    9000-Byte frame requires fewer IFG, preamble
    resulting in 0.1, a reduction of ten fold.

29
Performance comparison of EoS and EoB under
different traffic conditions.
EoB, Tg1
EoS
EoS
EoB, Tg5
EoB, Tg1
Ti burst aggregation time
30
Ethernet-over MPLS issues
  • What is Multi-protocol Label Switching (MPLS) ?
  • A data mechanism to provide a unified service for
    both circuit-based clients and packet-switching
    clients.
  • Supports various network technologies like ATM,
    IP etc.
  • MPLS sets up label-switched paths (LSP) for
    packets , thus saving time for a LSR (router) to
    look up the next node for forwarding the packet
    to.
  • Does not have common control and traffic
    engineering for wavelength , TDM and fiber
    switching.
  • Forwarding Equivalence class (FEC)
  • Set of packets with similar characteristics is
    forwarded the same way.

31

MPLS network
IP 2
B
IP 1
3
  • Working of a Label Switched Path

IP 2
3
C
IP 1
IP 3
A
IP 2
IP 3
32
Generalized Multi-protocol Label Switching (GMPLS)
  • Extends the MPLS functionality for TDM
    (labels-time slots) and FDM (labels
    electromagnetic frequency of light waves).
  • Ethernet tunnels provisioned dynamically to
    create wide-area- VLANs.
  • Peer-to-peer networking where CPE is part of the
    MPLS cloud.
  • Establishes space division multiplexed paths
    where labels indicate the position of the data.
  • Establishes common control plane between IP
    service management and optical layers.

33
VLL Virtual Leased Lines or Ethernet
tunnels. CPE Customer Premise
Equipment. PE Providers Edge
switch. VLAN (Virtual LAN) a group of
end-stations on multiple LAN segments and can
communicate as if they were on a single LAN.
34
  • CPE exchanges tables with the providers edge
    (PE) switches using GMPLS signaling.
  • Ethernet frame arriving at the CPE from local
    LANS carry the original Ethernet fields and
    802.1p/q headers (p- covers traffic class
    expediting and dynamic multicast filtering part
    of MAC bridges, q-defines services provided in
    Virtual LANs).
  • Frame is mapped to a FEC. FEC lookup yields the
    outgoing port and virtual circuit (VC) label,
    which is added to the frame and forwarded on the
    outgoing port toward PE switch.

35
  • The PE switch maps the Ethernet frame into an OBS
    burst and provides the required signaling by
    GMPLS label assignment in one of the following
    two addressing schemes,
  • 1. Flat assignment scheme
  • PE constructs a label forwarding base as shown
    below.
  • Like CPE label assignment , each label designates
    a unique LAN-MAC-FEC, one for each frame.
  • Only provides simple point to point connection.
  • Increases amount of labels and signaling.

36
  • 2. Hierarchical assignment scheme
  • Here each VLAN is assigned one VLL or LOBS label
    as shown in below.
  • So labels with same LOBS label aggregated in to
    the same burst.
  • Allows easy rerouting of VLAN traffic in event of
    failure.
  • Additional processing overhead.

37
  • PE looks up the incoming label, determines the
    VLAN, adds a LOBS label as shown below.
  • Frames with same LOBS label are aggregated into
    the same burst.

38
EoB path protection and restoration
  • 1. At WDM level
  • At optical layer, schemes match that of
    SONET but inflexible, subjects of current
    research.
  • 2. At Ethernet level
  • Spanning Tree Protocol (STP ) is used to provide
    redundant paths.
  • Long convergence time not suitable gtLOBS
    constantly setup and torn down.
  • 3. At GMPLS level
  • Head end - when path fails, OBS switch signals
    head-end switch to use a backup LOBS path.
  • Local reroute makes a local decision to
    redirect the burst.

39
  • Timely detour path is needed.
  • So, preestablished paths is essential in burst
    traffic.
  • Shortest reroute time gtdecision made as close to
    the failure point.
  • Since it takes time to inform the head node,
    local reroute mechanism is preferred.
  • Impossible to predict where failure may occur.
  • Every switch and link along the path is
    protected, detour paths setup dynamically at the
    same time primary paths are set up.

40
  • Local reroute requires establishing (N-1) detour
    paths as shown.
  • where N- number of OBS switches that the LOBS
    traverses.

41
Conclusion
  • Extending Ethernet services over OBS provides
    better scalability and bandwidth efficiency than
    with SONET.
  • SONET is limited by its TDM nature and by MP?S
    which does not provide statistical multiplexing.
  • As DWDM evolves more and more wavelength will be
    supported on each fiber.
  • Ethernet is best for LAN-MAN connectivity.
  • OBS provides efficient sharing of backbone
    resources.
  • GMPLS provides standard control mechanism to
    bridge distant MANs, provides protection with no
    permanent reservation of resources.
  • Providers improve their revenue stream and
    consumers reduce their network operational cost.

42
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