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SERENATE WP3 Equipment Study

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More specifically, to look at developments of routing, switching and ... all but a few vendors have either moth-balled their products or gone out of business ... – PowerPoint PPT presentation

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Title: SERENATE WP3 Equipment Study


1
SERENATE WP3Equipment Study
Valentino Cavalli, TERENAslides from Roberto
Sabatino, DANTE
2
WP3 (Equipment) Mission
  • A study of into the availability and
    characteristics of equipment for next-generation
    networks
  • More specifically, to look at developments of
    routing, switching and transmission equipment
    over the next 2-5 years
  • Efforts concentrated on addressing
  • higher capacities (i.e. 40Gbps)
  • optical technology for switching and transmission
  • developments in network management and the
    control plane
  • impact on network architectures

3
Work Plan
  • Bi-lateral meetings with 11 equipment vendors
    and 2 university research labs during November
    and December 2002
  • Equipment vendors
  • Alcatel, Calient, Ciena, Cisco, Corvis, Juniper,
    Lucent, Nortel, Photonex, Tellium, Wavium
  • e.g. cross-section of players from the well
    established to the newly started-up
  • University research labs
  • University of Essex (Prof Mike OMahoney)
  • University of Ghent (Prof Piet Demeester)
  • Attempted to contact a number of other vendors
    who either did not respond or declined to take
    part

4
Questionnaire
  • A confidential questionnaire was developed to
  • set the context of the bi-lateral meetings for
    the vendors (questionnaire was sent to them in
    advance)
  • provide some guidance for discussion during the
    meetings
  • Questionnaire addressed the following broad
    topics
  • 40Gbps capabilities (drivers technical
    difficulties)
  • Device scalability
  • New control plane paradigms
  • switching and transmission developments

5
The Team
  • DANTE (leader)
  • TERENA
  • NREN Consultants from
  • CESNET
  • PSNC
  • HEANet

6
Routing developments
  • Scalable to terabits, in multi-chassis platforms
  • require experts for installation?
  • 40Gbps backplane support and slot capability
    exists today
  • 40Gbps interface capability planned, but not
    yet available
  • SONET/SDH framing
  • coloured interfaces ?
  • Maybe but proprietary solutions

7
Router functionality
  • Differentiated Classes of Service
  • multicast
  • ipv6
  • MPLS-based VPNs
  • G-MPLS
  • following standards, expected improved
    interoperability
  • interdomain functionality still questionable

8
Switching developments
  • Optical Cross Connects (OXC)
  • Essentially digital cross connects with optical
    interfaces
  • Also called O-E-O switches
  • Photonic Cross Connects (PXC)
  • Devices that work entirely in the optical domain
  • Also called O-O-O switches

9
OXCs
  • Scale to hundreds of Gbps, using advanced ASICs
  • bandwidth grooming performed with proprietary
    techniques (not interoperable!)
  • GMPLS developments implementations still have
    proprietary features, although some
    interoperability demonstrated
  • Colour DWDM interfaces some proprietary examples
  • Will only work with same vendors transmission
    equipment

10
PXCs
  • All the rage a few years ago
  • Now all but a few vendors have either moth-balled
    their products or gone out of business
  • Can save on O-E-O conversions hence
  • footprint
  • power consumption
  • cost
  • Bit rate, protocol wavelength independence
  • Scale up to tens of Tbps switching capacity
  • Earliest envisaged use (of smaller products) as
    remotely manageable optical patch panel

11
PXC difficulties
  • re-routing of wavelengths leads to optical
    channels in different route length amplification
    and dispersion control difficult
  • QoS hard to control
  • Need external TDM devices for BW grooming
  • interoperability

12
Transmission equipment
  • Capabilities of current state-of-the-art DWDM
    transmission equipment far exceeds BW needs for
    the next few years
  • Little vendor interoperability amongst
    transmission components nor is this likely to
    happen
  • nature of systems is proprietary and analogue
  • only standards are ITU grid wavelength specs
  • may be possible to mix match for low capability
    systems (CWDM, lower bit rates e.g. 2.5Gbps)
  • Every DWDM link is bespoke
  • No off the shelf deployments

13
Reach
  • Very complex equation. Depends on
  • fibre type (G.652, G655.)
  • capacity of each wavelength
  • number of wavelengths
  • amplification technology used
  • transmission technology used
  • FEC

14
Reach with Nothing In Line (NIL)
  • Using pre and post amplification
  • up to 280km at 2.5Gbps (Cesnet experience) using
    RAMAN
  • using cheaper equipment (1GE, EDFA amplifier)
    result was 189km
  • 350km demonstrated

15
LH and ULH systems
  • LH (to 1,500km) and ULH (to 4,000 km) require
    amplification at each span (40-100km)
  • larger spans if less wavelengths (200km) at
    10Gbps
  • RAMAN
  • FEC
  • 40Gbps can reach 1,000km with 80km spans
  • RAMAN
  • dispersion compensation at receiver
  • PMD mitigators (depending on fibre)

16
Some conclusions
  • 40Gbps first in LH? Some say metro-area..
  • depends where economics work in its favour
  • common view is that main driver will be router
    interface cards
  • still more than 4x cost of 10Gbps
  • 80Gbps, 160Gbps technically possible, but in
    labs. (600Gbps has been demonstrated)

17
Network architectures
  • New set of requirements for research networks
  • traditional users at large
  • relatively limited number of users with
    requirements for limited coverage but very high
    capacity
  • accessibility of cheap wavelengths in some
    parts of Europe
  • developments of transmission technology
  • in some cases NRENS can do better without
    carriers

18
Network Options
  • Traditional IP (layer-3) only
  • mixed layer-2 layer-3, with OXCs (or PXCs)
  • Owned fibre network
  • a mix of all

19
Network Management and control
  • Different network architecture means NRENS will
    manage new network elements
  • Use traditional telco-style management systems as
    well as SNMP-based ones
  • Integration of two needs work!
  • G-MPLS has potential for integrated control, but
    interoperability and implementations conformant
    to standards not there yet
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