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Internet2 and JGN2: possible areas for collaboration

Internet2 and JGN2: possible areas for collaboration. Heather Boyles heather@internet2.edu. Some possible areas for collaboration. New network architectures/services Hybrid network architecture and services: shared IP and dedicated circuits Internet2 HOPI project and testbed

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Internet2 and JGN2: possible areas for collaboration

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  1. Internet2 and JGN2: possible areas for collaboration Heather Boyles heather@internet2.edu

  2. Some possible areas for collaboration • New network architectures/services • Hybrid network architecture and services: shared IP and dedicated circuits • Internet2 HOPI project and testbed • Performance Measurement and Monitoring Infrastructure • Interconnect our respective PM&M infrastructures • Architecture interoperability • Authentication and Authorization Infrastructure • Interconnecting national AAIs (e.g. US Internet2 InCommon Federation)

  3. Abilene Network – second generation

  4. Abilene timeline • Apr 1998 Network announced • Cisco Systems, Indiana Univ., Nortel Networks, and Qwest Communications initial partnership led by Internet2 • 2.5-Gbps national backbone (OC-48c SONET) • Jan 1999 Network went into production • Second generation network upgrade • Oct 2001 Qwest MoU (DWDM+SONET) extension (5 years) • Apr 2002 Routers from Juniper Networks added • Dec 2003 10-Gbps upgrade complete • Oct 2004 Transport agreement extended by one year • Oct 2007 Transport MoU with Qwest ends • The time frame for both next generation architecture finalization & decision on transport partner(s) is ~15 months from now early spring 2006.

  5. Abilene scaleSeptember 2004 • IPv4/v6-over-DWDM (OC-192c) backbone • 44 direct connections (OC-3c  10 GigE) • 2 (soon 3) 10-GigE connections (10 Gbps) • 6 OC-48c connections (2.5 Gbps) • 2 Gigabit Ethernet connections (1 Gbps) • 23 connections at OC-12c (622 Mbps) or higher • 230+ participants – research universities & labs • All 50 states, District of Columbia & Puerto Rico • Expanded access • 113 sponsored participants • 34 state education networks

  6. Abilene’s distinguishing features • Native advanced services – multicast & IPv6 • Ability to support large individual flows • Regular, routine testing: hourly 980+ Mbps TCP flows • Supporting multiple Internet2 Land Speed Records • Latest multi-stream TCP flow: 6.6 Gbps • Home for community’s advanced Internet initiatives • Middleware, for example • Cost recovery model • Pricing scales roughly logarithmically with bandwidth • Aim to is to encourage utilization and experimentation • Open measurement stance

  7. Applications End-to-end Performance Security Motivate Enable Middleware Services Networks Internet2 Today and Tomorrow

  8. Selection of activities/projects • Network Infrastructure • Abilene, Fiberco, Hybrid Optical Packet Infrastructure (HOPI), National Lambda Rail (NLR) support • Network Services • Abilene Observatory, IPv6, Multicast, Performance Measurement and Monitoring (end-to-end performance initiative) • International • Global coordination with NRENs around the world • Middleware • Authentication/Authorization tools (Shibboleth), Trust federation (InCommon) • Security • Security at Line Speed (SALSa) • Applications Collaboration environments (Internet2 Commons), Outreach to user communities (science & engineering; arts & humanities; health sciences)

  9. Collaborating on New Network Architectures and Services Development and Infrastructure Deployment

  10. HOPI Project - Summary • In the near future we will see a richer set of capabilities available to network designers and end users • Core IP packet switched networks • A set of optically switched waves available for dynamic provisioning • Fundamental Question: How will the core Internet architecture evolve? • Examine a hybrid of shared IP packet switching and dynamically provisioned optical lambdas • HOPI Project – Hybrid Optical and Packet Infrastructure • Have created a whitepaper – see http://hopi.internet2.edu • Immediate Goals • Implement testbed over the next year • Coordinate and experiment with other similar projects • Design Team, Corporate Advisory Team

  11. HOPI General Problem

  12. HOPI General Problem • How would one create a hybrid from these two infrastructures. The Nodes do switching and the links are point-to-point circuit like paths. Each link may have attributes – for example, bandwidth. Attributes may determine the ability to concatenate links. Examples include • Nodes are lambda switches with waves forming circuits – attributes include colors and bandwidth, etc. • Nodes are SONET switches with paths being SONET links – attributes include channels, etc. For example, OC-3, OC-12, etc. • Nodes are Ethernet switches with paths being point-to-point VLANS – attributes include bandwidth, etc. • HOPI will use this environment to examine different architectures • Nodes are routers on a packet infrastructure and the point-to-point paths are MPLS L2VPNs

  13. HOPI Questions • Examine how to build an architecture • A lot is known about how to do various pieces • The main question is how would one put it all together into a network • Problems to understand • When does a host use the circuit switched infrastructure and when does it use the packet infrastructure? • Temporal degree of dynamic provisioning • Temporal duration of dynamic paths and requirement for scheduling • Topological extent of deterministic provisioning • Examine backbone, RON, campus hierarchy – how will a RON interface with the core network? • Understand connectivity to other infrastructures – for example, international or federal networks? • Network operations, management, measurement, and control plane across administrative domains?

  14. HOPI Resources • The Abilene Network – MPLS tunnels and the packet switched network • The Internet2 Wave on the NLR footprint • MAN LAN Exchange Facility • TYCO/IEEAF 10 Gbps lambda NYC – Amsterdam • Cisco layer 2 and layer 1 switching gear • Significant addition of Nortel optical equipment to enhance layer 1 facilties • Collaborations with Regional Optical Networks (RONs) and other related efforts (GLIF, DRAGON, etc.)

  15. Abilene/NLR Map

  16. HOPI Basic Service • Given the available resources, we cannot use multiple waves to study new architectures – have only a single wave • Instead we’ll model waves using lower bandwidth “deterministic” paths – paths that resemble circuits – “lightpaths” • Basic service – A 1 or 10 GigE unidirectional point-to-point path with reasonable jitter, latency, and loss characteristics • Access – Direct to HOPI node or an MPLS L2VPN tunnel through Abilene

  17. HOPI Node • A fiber cross-connect switch (a white light switch) • Ability to switch the entire NLR wave to Abilene, to a RON, or to pass through the wave • An Ethernet switch device to partition the wave into 1 GigE paths when necessary • Control devices • Ad hoc control plane computer • Measurement computer • Experimental computer • Control and data planes must be disjoint • Out of band access

  18. Connector Interface • A 1 or 10 GigE connection to the FXC, either dark fiber or a provisioned service, including NLR • An MPLS L2VPN service through Abilene to the Ethernet switch or TDM device • Provides immediate connection to the Internet2 NLR wave from Abilene

  19. HOPI Deployment • Node locations • Los Angeles Equinix Facility – Support for CalTech and the HENP • The Pacific Northwest GigaPoP in Seattle • StarLight in Chicago • New York City – NYSERNet area in 32 AoA (Same location as MAN LAN, same building as Abilene Node) • Many thanks to NYSERNet for donating rack space and power to support the HOPI project • Washington, DC – Support for the Dragon Project • Hope to install in Seattle, Chicago and LA by end of calendar year. • New York and Washington, DC very early in January

  20. Collaborating on Performance Measurement & Monitoring Architecture and Infrastructure Deployment

  21. Internet2 E2E piPEs • Project: End-to-End Performance Initiative Performance Environment System (E2E piPEs) • Approach: Collaborative project combining the best work of many organizations, including DANTE/GEANT, Daresbury, EGEE, GGF NMWG, NLANR/DAST, UCL, Georgia Tech, etc. • NSF-sponsored workshop: http://e2epi.internet2.edu/WK03/index.html

  22. piPEs • Enable end-users & network operators to: • determine E2E performance capabilities • locate E2E problems • contact the right person to get an E2E problem resolved. • Enable remote initiation of partial path performance tests • Make partial path performance data publicly available • Interoperable with other performance measurement frameworks

  23. Measurement Infrastructure Components

  24. Project Phases • Phase 1: Tool Beacons • BWCTL (Complete), http://e2epi.internet2.edu/bwctl • OWAMP (Complete), http://e2epi.internet2.edu/owamp • NDT (Complete), http://e2epi.internet2.edu/ndt • Phase 2: Measurement Domain Support • General Measurement Infrastructure (Prototype) • Abilene Measurement Infrastructure Deployment (Complete), http://abilene.internet2.edu/observatory • Phase 3: Federation Support • AA (Prototype – optional AES key, policy file, limits file) • Discovery (Measurement Nodes, Databases) (Prototype – nearest NDT server, web page) • Test Request/Response Schema Support (Prototype – GGF NMWG Schema)

  25. piPEs Deployment

  26. American / European Collaboration Goals • Awareness of ongoing Measurement Framework Efforts / Sharing of Ideas (Good / Not Sufficient) • Interoperable Measurement Frameworks (Minimum) • Common means of data extraction • Partial path analysis possible along transatlantic paths • Open Source Shared Development (Possibility, In Whole or In Part) • End-to-end partial path analysis for transatlantic research communities • VLBI: Haystack, Mass.  Onsala, Sweden • HENP: Caltech, Calif. CERN, Switzerland

  27. Authentication and Authorization Infrastructure Development and Deployment

  28. Getting to a national AAI for inter-institutional collaboration • Internet2 Middleware Initiative launched 1999 • Focus on enterprise/campus • Focus on core middleware (that supports upperware e.g. grid middleware) • Focus on inter-institutional authentication and authorization; supporting collaboration, access to digital resources, virtual organizations • eduPerson attributes • Shibboleth authentication transport software • National Trust Federation (InCommon) initially built on institutions using Shibboleth

  29. Shibboleth Status • http://shibboleth.internet2.edu/ • Open source, privacy preserving federating software • Being very widely deployed in US and international universities • SWITCH (Switzerland has adopted) • JISC (UK) is adopting; funding development of complementary pieces • Growing development activities in several countries, providing resource manager tools, digital rights management, listprocs, etc.

  30. InCommon federation • Federation operations – Internet2 • Federating software – Shibboleth 1.1 and above • Federation data schema - eduPerson200210 or later and eduOrg200210 or later • Became operational April 5, with several early entrants to help shape the policy issues. • Precursor federation, InQueue, has been in operation for about six months and will feed into InCommon • http://incommon.internet2.edu

  31. International federation peering • Shibboleth-based federations being established in the UK, Netherlands, Finland, Switzerland, Australia, Spain, and others • International peering meeting held October 14-15 in Upper Slaughter, England • Issues include agreeing on policy framework, comparing policies, correlating app usage to trust level, aligning privacy needs, working with multinational service providers, scaling the WAYF function

  32. Why interconnect AAIs? • Support international collaborations between institutions • Researcher at Stanford working on a project with a Researcher at Keio University – utilizing a scientific instrument connected to the network at Stanford • Researcher at Keio authenticates to Keio U. system • Virtual organization (the researchers’ collaboration) authorizes locally authenticated users to access instrument

  33. The global league of AAIs • Expect we’ll utilize authentication and authorization services to: • Allow users to request, set-up ‘lightpath’ type services across our networks • Allow users and network managers to access performance measurement & monitoring data across PM&M infrastructure domains • Securely share security incident information between research network operators • Allow users to authenticate when making a video-conference call • Etc.

  34. AAI in Japan • Who sets up university campus-wide authentication systems? • Is there any coordination at national level in Japan toward national AAI to support inter-institutional collaboration? • If so, who is coordinating? • If not, how can we help get this going?

  35. What are JGN2 interests? • Are there other areas where Internet2 and JGN2 should be collaborating?

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