1 / 24

Pacific NorthWest Gigapop, Pacific Wave & International Peering

Pacific NorthWest Gigapop, Pacific Wave & International Peering. David Morton, PNWGP RENU Technology Workshop. Introduction. Our many jobs: University of Washington Pacific Northwest Gigapop Pacific Wave Operate regional and state networks

byrd
Download Presentation

Pacific NorthWest Gigapop, Pacific Wave & International Peering

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Pacific NorthWest Gigapop, Pacific Wave & International Peering David Morton, PNWGP RENU Technology Workshop

  2. Introduction • Our many jobs: • University of Washington • Pacific Northwest Gigapop • Pacific Wave • Operate regional and state networks • Pacific Northwest Gigapop (PNWGP) - Regional and International interconnection point for: • Pacific Wave (including IEEAF link to Tokyo) • National R&E Networks (National Lamba Rail, Internet2) • Regional and State networks (Northern Tier, K20, other Universities in the region • Enabling advanced research in a wide variety of topics. Pacific Wave & International Peering

  3. The Direct Connections Pacific Wave & International Peering

  4. Pacific Wave • A joint project between Corporation for Education Network Initiatives in California (CENIC), Pacific Northwest Gigapop (PNWGP), University of Southern California (USC), and University of Washington (UW) • A distributed Internet Exchange Point (IXP) running the length of the entire United States Pacific Coast • Supports high-end networking and protocols, including IPv4 (ucast/mcast), IPv6 (ucast/mcast), Jumbo Frames Pacific Wave & International Peering

  5. Pacific Wave Initial Services • Provide an open infrastructure for connecting international IP networks • Facilitate any-to-any connectivity between connectors without the need for involvement of exchange operators • Primary connectivity provided via shared VLANs • Private VLANs used sparingly on as-needed basis Pacific Wave & International Peering

  6. Characteristics of the Service Offering • Distributed connectivity using shared broadcast domains • Strict connector policy to ensure high availability and uptime • Single MAC per VLAN • No direct connection of layer-2 switching devices • Spanning tree root guard Pacific Wave & International Peering

  7. What is a Distributed IXP? • A switching fabric that extends beyond the confines of a small geographic region which Internet exchange points typically operate • Capable of providing direct connectivity between entities which do not share common, physical presences due to financial, operational, or logistical constraints • An architecture which does not define any central or primary point in the infrastructure Pacific Wave & International Peering

  8. Shared VLAN Infrastructure • Local, shared VLANs • Seattle • SF Bay Area • Los Angeles • Intersite, shared VLANs • Seattle - SF Bay Area • SF Bay Area - LA • Seattle - LA • Standard MTU and Jumbo MTU overlay Pacific Wave & International Peering

  9. Underlying Infrastructure • Exclusively Cisco 7600 and 6500 class devices with Sup720 • Redundant supervisor modules at critical points • All linecards are 67xx series fabric enabled • Strategic termination of TenGigE links based on fabric utilization • PIM-SM snooping used to contain multicast traffic Pacific Wave & International Peering

  10. Layer-1 Infrastructure • Seattle • Nortel HDXc co-operated with Canarie • Cisco IEEAF ONS 15454 MSPP • 4 ML1000-2 line cards (Capable of GFP-F and LEX) • KREONet2 ONS 15454 MSPP • Los Angeles • CENIC ONS 15454 MSPP • AARNet ONS 15454 MSPP Pacific Wave & International Peering

  11. Combined Layer-1 and Layer-2 Infrastructure Pacific Wave & International Peering

  12. Wide Area Connectivity • TenGigabit Ethernet LAN-PHY circuit provisioned via NLR, Seattle to Sunnyvale • TenGigabit Ethernet LAN-PHY circuit provisioned via CENIC , Sunnyvale to LA Pacific Wave & International Peering

  13. Physical Topology • Five 65/7600 layer-2 switches • Deployed over NLR and CENIC 10g lambdas • Seattle • Westin • SF Bay Area • Sunnyvale (Level 3) • Palo Alto (PAIX) • Los Angeles • One Wilshire • Equinix (600 W 7th) • Equinix (818 W 7th) Pacific Wave & International Peering

  14. NLR Enables Pacific Wave Pacific Wave & International Peering

  15. International Participation Pacific Wave & International Peering

  16. Pacific Northwest Participation Pacific Wave & International Peering

  17. Examples of Collaborations • WIDE/TLEX-PNWGP (IEEAF Tokyo - Seattle): Data Reservoir; HD Video • AARNet (SX-Transport Sydney to Seattle): Huygens Data Transfer • CA*Net4: Data Reservoir and Huygens Data Transfer • ESNet/UltraScienceNet: SuperComputing 2005 • National LambdaRail: SuperComputing 2005, iGrid 2005 • OptiPuter Chicago - Seattle - San Diego: iGrid2005, HD Video • Abilene: HD Video • KREONet2 (GLORIAD Daejon - Seattle): HD Video Pacific Wave & International Peering

  18. GLIF (Global Lambda Integrated Facility) Pacific Wave & International Peering

  19. Pacific Wave Optical Lightpath Exchange (GOLE) Diagram Pacific Wave & International Peering

  20. The Hybrid Approach • The hybrid exchange operator can provide easy interconnection between layer-1 and layer-2 devices as necessary • Today: manual with physical cross-connect • Future: optically switched manually or via control plane protocols • Technology choices made based on: • Performance requirements • Bandwidth requirements • Timeframe desired for lightpath activation • Availability of wide-area transport Pacific Wave & International Peering

  21. A Distributed GOLE? • A term as yet defined in the GLIF community • What properties might a distributed GOLE (GLIG Optical Lightpath Exchange) have? • Multi-transport interconnect between nodes • Layer-1 lambda • Layer-2 frame mapped (i.e. GFP-F) • Layer-2 switched • Able to make establish lightpaths between and through the nodes with the efficiency of a single operating entity • No bandwidth limitations between nodes (within reason…) Pacific Wave & International Peering

  22. Future • Today, Pacific Wave layer-2 switching is a series of linear interconnected fabrics • Perhaps more complex wide-area topologies may one day be necessary on the layer-2 network • Bandwidth management • Resiliency • MPLS layer-2 Ethernet VPNs may provide additional opportunities to support future requirements • Optical switching facilitates efficient lightpath establishment, especially during technology translation, i.e. frame-mapped  switched Ethernet Pacific Wave & International Peering

  23. Thank You dmorton@u.washington.edu

  24. An Amazing Feat at SC05 Pacific Wave & International Peering

More Related