GMPLS WG PIL GMPLS 2004.2.17 NTT Photonic Internet Labs. 1 Outline Introduction HIKARI network Universal control Scalable service Universal / cost effective backbone network HIKARI-router PIL GMPLS Photonic Internet Lab. (PIL) GMPLS Conclusion 2
1998 1999 2000 2001 2002 2003 Traffic Demand 40.0 30.0 20.0 10.0 0.0 (Gb/s) ADSL ISDN ADSL 8M B ( ) ADSL 12M 1000 500 ( ) 0 3 Future HIKARI (Photonic) Network 2002 2003 2004... year Scalable service Bitrate restriction OVPN free network Active mirroring service Virtual NW λ-network Universal Network Adaptive 3R Wavelength conversion waveband SW Universal control GMPLS Ultra-scalable network GSMP HIKARI backbone service [A] Universal control [B] Scalable service VPN GMPLS CDN Distributed IX/IDC GbE 10GbE ATM Adaptive transparent SONET/SDH cut-through Analogue TV [C] Universal network (Low cost) 4
[A] Universal control IP Integrated node ATM SDM GMPLS-based universal control WDM 5 [B] Scalable service (1) Scalability for interface ATM STM Ether Analog Any interface Transparent User A -NW VPN ID#2 UNI VPN ID#1 (ex) OVPN service with L1 scalability User B -NW UNI VPN ID#1 User A -NW VPN ID#2 User B -NW STM GbE UNI Control plane User A Transport plane -NW Provider NW VPN ID#1 VPN A SDH GbE 6
[B] Scalable service (2) ATM NTT s ATM/SDH ATM 1 month NTT s GbE NTT VPN 1hr Universal 1hr Network 7 [B] Scalable service --- OVPN, first implementation Quasi-transparent network for multi-interface Universal frame for capsulling multi-protocol Control plane UNI-C CE Transport plane OUNI Optical L1 UNI-N Optical SW Universal frame STM Ether ATM L1 converter PE OXC Universal frame ATM Quasi- Transparent network UNI UNI ( ) 2R/3R 8 CE CE
[C] Universal network Low cost Multi-layer traffic engineering -> High-efficient resource utilization Adaptive transparent with minimum number of wavelength conversion ->Transparent cut-through 9 Multi-layer backbone network design Traffic matrix Decrease traffic Increase traffic OLSP 10
Optical path topology design Average node degree D 12 α/β= 10 10 8 6 4 2 0 0 0 500 1000 1500 2000 2500 0 500 1000 1500 2000 2500 Traffic demand between S-D pairs, T [Mbit/s] Traffic demand between S-D pairs, T [Mbit/s] (1) Optical photonic lagical topology (2) Cost reduction effect Normalized network cost 1 0.8 0.6 0.4 0.2 Fixed topology α/β= 10 Changing topology Network cost reduction 11 Optical transparent path L3 Forwarding LT/OE/WC λ1 λ1 LT LT (a) L3 forwarding Ingress edge (b) λ-relay (c) Optical transparent path Egress edge Transmission segment 12
Adaptive transparent path Best path WCC ij red plane blue plane green plane Link cost Wavelength conversion Network cost reduction % (Photonic GMPLS/Electrical MPLS) 120 100 80 60 40 20 0 0% Electrical MPLS network Cut-through 70 80 % cost reduction Adaptive wavelength conversion 20% 40% 60% 80% 100% Through traffic using OLSP 13 Outline Introduction HIKARI network Universal control Scalable service Universal / cost effective backbone network HIKARI-router PIL GMPLS Photonic Internet Lab. (PIL) GMPLS Conclusion 14
HIKARI router (1) Type-A Type-B Type-C WDM DMUX Optical Path Optical SW Monitor L1-Trunk λ-conv. 3R IP/MPLS router#1 FE FE S w Router#2 L2-SW #1 Monitor Multicast Photonic GMPLS router manager Hardware structure L2/L3-Trunk Photonic link state Type-C (Layer 3 Packet forwarding) Type-B (Optical 3R or wavelength conversion path) Type-A (Optical transparent path, Bit-rate restriction free) IP link state Multi-layer topology design algorithm GMPLS controller Hardware manager IP traffic monitor with low-pass filter OSPF extension RSVP-TE extension Software structure LRU=WDM+Optical SW +L1-Trunk LRU : Lambda Routing Unit FE : Forwarding Engine SW : Switch l-conv : Lambda converter NE : Network Element 15 IP/MPLS 16
Outline Introduction HIKARI network Universal control Scalable service Universal / cost effective backbone network HIKARI-router PIL GMPLS Photonic Internet Lab. (PIL) GMPLS Conclusion 17 18
IETF Running code IETF Runnig Code A A Code B B Code RFC, IA 19 GMPLS IETF GMPLSPIL OEO SONET IP IETF Lambda Switch (AON) IP-SONET- IP SONET Lambda OEO Lambda switch AON OOO (AON) 20
PIL PIL PIL Give & Take 21 IETF (Leading-edge code) IETF + Leading-edge code A A (Leadingedge) Code A A B B Code A B B C C IETF Code IETF C C OIF RFC, IA OIF ITU-T ITU-T 22
PIL 2002 9 NTT NEC 6 2003 3 7 Give & Take WG H14 H14 3 NTT PIL WG WG Leading Edge PIL NEC NTT 39 23 WG WG ITU-T IETF OIF IETF PIL 10 1 WG Leading Edge GMPLS RSVP-TE PIL 2002 2 19 24
[1] draft-shiomoto-ccamp-multiarea-te-01.txt [11] draft-vigoureux-shiomoto-ccamp-gmpls-mrn-00.txt -GMPLS - Generalized (Multi-area multi-layer traffic engineering MPLS Architecture for Multi-Region Networks using hierarchical LSPs in GMPLS networks) [12] draft-matsuura-reverse-lsp-01.txt [2] draft-imajuku-ml-routing-02.txt -GMPLS (Signaling reverse-directional - LSR LSP in generalized MPLS) Multilayer routing using multilayer switch capable LSRs [13] draft-ietf-gsmp-reqs-04.txt [3] draft-matsuura-mpls-reverse-lsp-00.txt -GMPLS (Signaling reverse-directional LSP - GSMP (Requirements for adding optical support to GSMPv3) in generalized MPLS) [14] draft-czezowski-optical-recovery-reqs-01.txt [4] draft-vigoureux-ccamp-gmpls-architecture-hpn-00.txt - GMPLS (Generalized - Optical Network Failure Recovery Requirements MPLS architecture for multi-region networks) [15] draft-rabbat-fault-notification-protocol-02.txt [5] draft-oki-ipo-optlink-req-00.txt - Fault Notification Protocol for GMPLS-Based Recovery - [16] draft-soumiya-lmp-fault-notification-ext-00.txt (Requirements of optical link-state information for traffic engineering) - Extensions to LMP for Flooding-based Fault Notification [6] draft-oki-ccamp-upstream-labelset-00.txt [17] draft-shimano-imajuku-gmpls-restoration-00.txt - RSVP-TE (Upstream label - extensions for gmpls restoration signaling set support in RSVT-TE extensions) [18] draft-matsuura-reverse-lsp-02.txt [7] draft-matsuura-gmpls-rsvp-requirements-01.txt -GMPLS RESV-TE Requirements for -GMPLS (Signaling reverse-directional LSP in generalized MPLS) using RSVP-TE in GMPLS signaling [19] draft-ietf-ccamp-gmpls-recovery-terminology-01 [8] draft-suemura-gmpls-restoration-signaling-00.txt - Recovery (Protection and Restoration) Terminology for - RSVP-TE GMPLS (Extensions to RSVP-TE for Supporting Multiple Protection and Restoration Types) [20] draft-papadimitriou-ccamp-gmpls-recovery-analysis -03 - Analysis of Generalized MPLS-based Recovery Mechanisms [9] draft-czezowski-optical-recovery-reqs-00.txt (including Protection and Restoration) - Optical Network Failure Recovery Requirements [10] draft-seno-path-quality-verification-00.txt - Path Quality Verification over an All- Optical Network [21] draft-bala-gmpls-recovery-functional-01 - Generalized MPLS Recovery Functional Specification 25 EtherReal NEC NTT NT T LSC PSC TDM LSC FSC NEC NEC 26
2003 5 21 2003 5 21 2003 5 21 27 PIL 2.5 400 PIL http://www.pilab.org/ PIL 28
MPLS2003 PIL MPLS / GMPLS demo Oct. 27-29, 2003 @ Washington DC PCによるGMPLS相互接続および MPLS/GMPLS連携技術をデモを実施 各社の技 術成果をアピールした LSC PSC PSC MPLS MPLS LSC TDM TDM 波長のパス Node 0 パケットのパス MPLS Node 1 パケットのパス GMPLS Node 4 Node 2 波長のパス TDMのパス Node 3 Node 6 Node 5 TDMのパス Node 8 Node 7 GMPLS domain MPLS domain 29 MPLS2003でPILが公開実験した技術 MPLSからGMPLSへのマイグレーション技術 MPLS網にGMPLSを導入する際に 既存MPLSルーターに対してど のようにGMPLS網を意識させるかについてルーティング シグナリン グ 制御プレーンの連結について問題提起と解決法を提案 ルーティングに関してはFA-LSPを設定したボーダールータ間のリンク をOpaque-LSAまたはRouter-LSAとして広告することを提案 シグナ リングに関してはトネリングとスティッチングの方法を提案 制御プ レーンの連結について問題提起 draft-oki-ccamp-gmpls-ip-interworking-01.txt (IETFドラフトを提出) G2 IP topology view R1 G1 R1 G3(adv) G1(adv) GMPLS topology view G4 R3 G6 G1 R3 G3 R2 G5(adv) G6(adv) G7(adv) G5 G2 G6 G3 G4 G7 R2 G5 G7 G8 G9 G8 G9 30 15
GMPLS IP MPLS NTT 4 IP MPLS MultiProtocol Label Switching GMPLS Generalized MultiProtocol Label Switching MPLS IP IP 31 2003.10.27 32
BUSINESS WIRE, October 27, 2003 (10/27/2003) MPLS 2003 International Conference and Exhibits Opens in Washington, DC BUSINESS WIRE October 27, 2003; McLean, Virginia Isocore today announced the opening of the MPLS 2003 International Conference which will provide a forum for leading MPLS vendors, test equipment manufacturers, and premier ISPs to showcase next generation MPLS products and services. ( ) Also participating at the exhibits is NTT Network Systems Laboratories demonstrating world's first Multicast MPLS protocol jointly developed with Motorola. The demo will shows various data distributing scenarios over traffic engineered multipoint LSPs. Additionally, NTT, NEC Corporation, Furukawa Electric Co., Ltd., and Mitsubishi Electric Corporation will highlight PIL's activities. 33 BUSINESS WIRE, October 29, 2003 (10/29/2003) 10/29/2003 Sycamore Demonstrates Multi-vendor IP/Optical Interoperability Featuring MPLS Services over an Intelligent Optical Core Sycamore's SN 16000 Intelligent Optical Switch successfully demonstrates standards-based GMPLS signaling and routing Chelmsford, Mass. - Sycamore Networks, Inc. (NASDAQ: SCMR), a leader in intelligent optical networking, today announced that the company successfully demonstrated Generalized Multi-Protocol Label Switching (GMPLS) multi-vendor interoperability in Isocore's IP/Optical Integration demonstration -- held in conjunction with the MPLS 2003 International Conference - - at the Isocore Internetworking Lab in McLean, Va. on Wednesday, October 29. "By unifying network operations between the IP and optical layers, GMPLS provides the means for service providers to reduce operations costs and improve network efficiencies," said Naoaki Yamanaka, Ph. D., of NTT Network Innovation Laboratories. "Validating the inter-working of IP/MPLS and GMPLS is an important step in the evolution toward more flexible next-generation optical networks." 34
PIL 2003.6.13 2004.1.1 35 PIL Network NW Global NTT H14 CRL PIL NTT NW 7 2 ISOCORE NTT PIL PIL 36
IP+Optical GMPLS visibility Running Code PIL 37