Interoperability effort for ubiquitous Interoperability effort for ubiquitous GMPLS controlled optical networks - Activities of the Kei-han-na Open Labs. - Satoru OKAMOTO <[email protected]> Keio University Tomohiro OTANI <[email protected]> KDDI R&D Labs. www.mpls2008.com
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Interoperability effort for ubiquitousInteroperability effort for ubiquitous GMPLS controlled optical networksp
Kei-han-na Info-Communication Open Labo ato iesLaboratories.Activities of the interoperability Working Group
10 GbE-LAN PHY direct mapping over OTNpp gInter-Carrier PCE based path computingASON/GMPLS interworkingASON/GMPLS interworkingL2SC Multi-domains interworking
SSummary
2
Kei han na Info Comm nication OpenKei-han-na Info-Communication OpenLaboratory Overview
Established at 2003To establish a global-standard info-communication sectors inTo establish a global-standard info-communication sectors in Japan “Kansai” region through industry, academia, and government collaboration. National Institute of Communication Technology (NICT) provides rental lab space and rental research facilities.
IP routers, TDM-XCAccess point to the JGN2-plus network
Creating new industries and services
Human resource development
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Organization of the Kei-han-na Info-gCommunication Open Laboratory
(2006-)(2006 )General Assembly of the Council
Board of Directors
SecretariatInteroperability WG2.0
Working Groups (WGs)
Operation and Research Committee
Interoperability WG2.0
PJ21: 10GE LAN-PHY over OTN technologies
Sub CommitteesPlanning and Publication
PJ22: GMPLS E-NNI and all optical network control protocolPJ23: New generation 100GE t i i d t l
Sub Committees
New Generation Networktransmission and control
Human Communications
Photonic
N k A li i
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Universal & Robot CityNetwork Application
Interoperability WG 2.0 R&D items
Ethernet based transmission network hierarchy
New Generation Ethernet transmission and control40GE & 100GE OTN t h l i40GE & 100GE over OTN technologiesTerabit LAN GMPLS t ll d Eth tGMPLS controlled Ethernet
will be demonstrated at EXHIBITION
GMPLS E NNI d ll ti l t k t l t lGMPLS E-NNI and all optical network control protocolMulti-layer inter-carrier E-NNII t D i /I t C i PCEInter-Domain/Inter-Carrier PCE
will be demonstrated at EXHIBITIONAll optical network control for ROADM and PXCAll optical network control for ROADM and PXC
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10GbE LANPHY direct mapping technolog10GbE-LANPHY direct mapping technology over OTN
"OTN (Optical Transport Network)" has been standardized at ITU-Tat ITU T.
Bit rate is optimized for SDH/SONET.
Simple 10GbE signal directly mapping into OTN is requiredSimple 10GbE signal directly mapping into OTN is required.Interoperability test at Kei-han-na site with 10 carriers/vendors.
Inter-carrier diverse route set up for WDM networksP i th l l ti ith P th K IDPrimary path calculation with Path Key IDSecondary path calculation with XRO
Routing InterworkingBGP TE extensionBGP-TE extension
End-point information (address, interface ID, switching capability and adaptation information)capability, and adaptation information)
GMPLS domainASON domain
LSC Network LSC Network
ASON domain
GWUNI E-NNI
BGP-TE
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BGP-TE - Scalability Problem ?
draft-ietf-softwire-bgp-te-attribute-03.txt @ Sept. ‘08Within AS (use for iBGP)Within AS (use for iBGP)The scope and applicability of this attribute currently excludes its use for non-VPN reachability information.use o o eac ab ty o at o
AS should be separated between IP/MPLS networks and non-IP (e.g. GMPLS) networks.non IP (e.g. GMPLS) networks.
No eBGP peer between IP/MPLS networks and GMPLS networks.
/IP/MPLS
AS #1 AS #2R ReBGP peer
R : Border Router
AS #3 AS #4R RXCXCGMPLS GMPLS
R : Border Router
XC : Border Cross‐Connect
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AS #3 AS #4R RXCXC
eBGP peer
L2SC Multi-domains interworking [4][5]
GMPLS controlled EthernetN t PBB TENot PBB-TE
Tag-VLAN vs. Port-VLANTag-VLAN only, Port-VLAN only, and Mixed Tag and Port-VLAN
Label swapping at each nodeIndicates Tag/Port VLAN-ID Physical Port - Keio/NICTIndicates Tag/Port, VLAN-ID, Physical Port - Keio/NICTIndicates pointer of preconfigured data – KDDI
T 3 L b l ERO S b Obj t i dType-3 Label ERO Sub-Object is used.
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First Demonstration @ iPOP2008
N KeNN
ASON/NICTAS#3002
GMPLSKeio, NICT, KDDI
AS#3001UNI‐C UNI‐N
NN Ke
E‐NNI
192.168.0.0/24 172.19.0.0/16172.18.0.0/16
GRE GRE GRE GRE GRE GRE
E‐NNI
ControlPC
KeKDKD
GMPLS/KDDIAS#3003
ASBRASBRKeKDKD
172.16.0.0/16
GREGREGREGREGRE
192.168.1.0/24GREGRE
ControlPl Vi ASBRASBRPlane View
DataPlane View Tag+PortPort+Tag Tag
N N N N Ke Ke
Plane View
EthernetS it h
gPort Tag
Port
Tag
KeKeKDKDKDKD
Switch Port Port
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New Trial(1): BGP-TE interoperability
Proprietary BGP-TE implementationsAlign with draft-ietf-softwire-bgp-te-attribute-xxAlign with draft-ietf-softwire-bgp-te-attribute-xx
Interworking with BGP-TE and OSPF-TEExtension of Node Attribute TLV or L1VPN LSAExtension of Node Attribute TLV or L1VPN LSA
N KeNN
ASON/NICTAS#3002
GMPLSKeio, NICT, KDDI
AS#3001NN Ke
GWN KeNN AS#3001
GMPLS/KDDI
UNI‐C UNI‐NNN Ke
E‐NNI E‐NNI
KeKDKDAS#3003
ASBRASBRKeKDKD
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New Trial(2): E-NNI less signaling GW
Signaling interworking between E-NNI and [I-NNI (RSVP-TE)[6] | GMPLS RSVP-TE] becomes popular techniqueTE)[6] | GMPLS RSVP TE] becomes popular technique.
Signaling GW is located in the GMPLS domain.
Signaling GW located in the ASON domain is also possibleSignaling GW located in the ASON domain is also possible.
N KeNN
ASON/NICTAS#3002
GMPLSKeio, NICT, KDDI
AS#3001NN Ke
GWGWN KeNN AS#3001
GMPLS/KDDI
UNI‐C UNI‐NNN Ke
E‐NNI E‐NNI
KeKDKDAS#3003
ASBRASBRKeKDKD
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Summary
Activities of the Kei-han-na Info-Communication Open Lab Were describedLab. Were described.
Interoperability testing of over-clocked 10GbE-LAN PHY O ti l T t N t kover Optical Transport Network
Inter-Carrier PCE based diverse path calculationASON and GMPLS domains interworkingMulti-domain GMPLS controlled Ethernet
Inter-Domain/Inter-Carrier interoperability is one of the most important work for deploying the IP/the most important work for deploying the IP/ Ethernet over Optical Network services.
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Acknowledge
This presentation is partially supported by SCOPE f th Mi i t f I t l Aff i dSCOPE program of the Ministry of Internal Affairs and Communications (MIC) of Japan.“ bd ” f d d b h l“Lambda Access Project” funded by the National Institute of Information and Communications T h l (NICT)Technology (NICT).
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References
[1] T. Takeda, E. Oki, Y. Iizawa, I. Nishioka, M. Asaie, K. Kusama, S. Okamoto, and T. Otani, “Inter-Carrier PCE-Based Path Computation in Keihanna Interoperablity Project” T3 1 iPOP2008 June 2008Project”, T3-1, iPOP2008, June 2008.
[2] S. Okamoto, T. Otani, Y. Sone, K. Ogaki, M. Miyazawa, I. Nishioka, K. Miyazaki, A. Nagata, D. Ishii, S. Okamoto, N. Arai, and H. Otsuki , “Field Trial of Signaling I t ki f M lti i ASON/GMPLS N t k D i ” PDP47 OFC/NFOECInterworking of Multi-carrier ASON/GMPLS Network Domains”, PDP47, OFC/NFOEC 2006, March 2006.
[3] S. Okamoto, H. Otsuki, and T. Otani, “Multi-ASON and GMPLS Network Domain I t ki Ch ll ” IEEE C i ti M i V l 46 N 6 88 93Interworking Challenges”, IEEE Communications Magazine, Vol. 46, No. 6, pp. 88-93, June 2008.
[4] H. Otsuki, D. Ishii, K. Kikuta, S. Okamoto, S. Okamoto, and T. Otani, “L2SC Inter-Carrier Interface Interoperability Trial”, MPLS 2007, 314, Oct. 2007.
[5] D. Ishii, K. Kikuta, S. Okamoto, and N. Yamanaka, “An Experiment of Controlling Gigabit Wide Area Ethernet by GMPLS supporting Layer-2 Switching Capability”, OFC/NFOEC2008, OThB5, Feb. 2008.
[6] OIF-G-Sig-IW-01.0, “OIF Guideline Document: Signaling Protocol Interworking of ASON / GMPLS Network Domains”, June 2008.