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OSPF Extensions in support of O-E-O pools in GMPLS controlled all-optical networks draft-peloso-ccamp-wson-ospf-oeo-01 Pierre Peloso, Julien Meuric, Giovanni.

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Presentation on theme: "OSPF Extensions in support of O-E-O pools in GMPLS controlled all-optical networks draft-peloso-ccamp-wson-ospf-oeo-01 Pierre Peloso, Julien Meuric, Giovanni."— Presentation transcript:

1 OSPF Extensions in support of O-E-O pools in GMPLS controlled all-optical networks draft-peloso-ccamp-wson-ospf-oeo-01 Pierre Peloso, Julien Meuric, Giovanni Martinelli

2 draft-peloso-ccamp-wson-opsf-oeo-01 2 | OSPF-TE extensions for WSON | IETF 77th Rationales for this work Target: Flooding of information through OSPF-TE to provide a graph to compute both spatial and spectral assignment of a LSP into an all-optical meshed network (WSON). Issues to solve: Not only flooding of wavelength availability inside links, but also: Switching constraints (spatial and spectral) inside nodes (between links) Description of O-E-O resources inside nodes (for regeneration or conversion purposes) Their availability Their features Their accessibility

3 draft-peloso-ccamp-wson-opsf-oeo-01 3 | OSPF-TE extensions for WSON | IETF 77th Summarizing table of information to be conveyed through IGP Links related features Wavelength availability Node related features physical switching constraints for node bypassstatic spectral switching constraints for node bypassstatic regenerators/converters availabilitydynamic regenerators/converters featuresstatic Signal features Wavelengths that can be handled regenerators/converters accessibility spatial static spectraldynamic Next slides provide examples of architectures that illustrate the different node related features

4 draft-peloso-ccamp-wson-opsf-oeo-01 4 | OSPF-TE extensions for WSON | IETF 77th Fully flexible Y-node with 1 tunable and flexible pool of O-E-O From node A From node B From node C To node A To node B To node C add drop … … Tun. Drop Tun. Drop OEO pool

5 draft-peloso-ccamp-wson-opsf-oeo-01 5 | OSPF-TE extensions for WSON | IETF 77th Partially Fixed ROADM From node A To node C drop Tun. Drop add OEO pool

6 draft-peloso-ccamp-wson-opsf-oeo-01 6 | OSPF-TE extensions for WSON | IETF 77th Fully flexible Y node with 4 tunable pools of O-E-O fixed to links From node A From node B From node C To node A To node B To node C Tun. Drop Tun. Drop Tun. Drop OEO pool 1 OEO pool 3 OEO pool 2 OEO pool 4

7 draft-peloso-ccamp-wson-opsf-oeo-01 7 | OSPF-TE extensions for WSON | IETF 77th Technical description of the OSPF-TE modifications Provide an OSPF-TE layout that intrinsically separates some static info from some dynamic ones, exploiting the concept of OEO pools Have LSA for WDM links with availability of wavelength (dynamic) Have LSA for switching constraints of nodes (static) Have LSA for OEO resources (static and dynamic) A B C D OEO pool

8 draft-peloso-ccamp-wson-opsf-oeo-01 8 | OSPF-TE extensions for WSON | IETF 77th Illustration of LSAs layout A C D A C D OEO pool LSA Node B LSA Connectivity Matrix Ingress ports Egress ports WDM links LSAs

9 draft-peloso-ccamp-wson-opsf-oeo-01 9 | OSPF-TE extensions for WSON | IETF 77th LSA describing WDM links - referring to draft-zhang-ccamp-rwa-wson-routing-ospf-03 Description of the fields of the Link TLV (top level TLV : type 2) within LSA type 1O (Opaque LSA) – Opaque Type 1 (TE-LSA) –Link type rfc3630 1 BytePt-Pt or Pt-MPt –Link ID rfc3630 4 BytesIP Address of the egress node of the link –Local interface IP address rfc3630 4 Bytes IP Address of the ingress node –Remote interface IP address rfc3630 4 Bytes IP Address of the egress node of the link –Traffic engineering metric rfc3630 4 Bytes TE value settable by operator –Maximum bandwidth rfc3630 4 Bytes Maximum Bandwidth –Unreserved bandwidth rfc3630 4 Bytes Unreserved Bandwidth –Resource class/color rfc3630 4 Bytes Administrative value settable by operator –Link Local/Remote Identifiers rfc4203 8 Bytes Two identifiers identifying interfaces at both ends of the link (values local to related node) –Link Protection Type rfc4203 4 Bytes Describes the protection (usually unprotected) –Shared Risk Link Groups (SRLGs) rfc4203 4N Bytes Group of common risks (e.g. same fiber duct) –Interface Switch Cap Descriptor rfc3630, rfc4203 4N Bytes Describes the switch cap a priori LSC –Wavelength restriction4N Bytes Wavelength restriction –Available wavelengths4N Bytes Bitmap mask for available Wvl –Shared Backup wavelengths4N Bytes Bitmap mask for available Wvl

10 draft-peloso-ccamp-wson-opsf-oeo-01 10 | OSPF-TE extensions for WSON | IETF 77th LSA describing WDM nodes Description of the fields of the Node Attribute TLV (top level TLV : type 5) within LSA type 1O (Opaque LSA) – Opaque Type 4 (RI-LSA) –Node Local Address draft-ietf-ospf-te-node-addr 4 BytesLocal IP Address of the node –Connectivity Matrix 4N BytesDescription of connectivity constraints of the node, both spatial and spectral Connectivity matrix shall list interfaces of: Incoming and outgoing WDM links OEO pools

11 draft-peloso-ccamp-wson-opsf-oeo-01 11 | OSPF-TE extensions for WSON | IETF 77th LSA describing OEO resources Description of the fields of the Link TLV (top level TLV : type 3R) within LSA type 1O (Opaque LSA) – Opaque Type 1 (TE-LSA) –Pool ID 4 BytesID of the Pool –Traffic engineering metric rfc3630 4 Bytes TE value settable by operator –Resource class/color rfc3630 4 Bytes Administrative value settable by operator –Link Local/Remote Identifiers rfc4203 8 Bytes Two identifiers identifying interfaces at both ends of the link (values local to related node) –Ingress Available wavelength4N Bytes Bitmap mask for available Wvl to the pool –Egress Available wavelength4N Bytes Bitmap mask for available Wvl from the pool –Ingress Transponder infoFixedID and features of ingress side of a OEO device –Egress Transponder infoFixedID and features of egress side of an OEO device –Shared Risk Link Groups (SRLGs) rfc4203 4N Bytes Group of common risks (e.g. same shelf) Transponder info shall describe the features of OEO devices and there shall be a list of those (as many instances as OEO devices in the pool). It contains a description of the features of a given device: Local Device ID Signal compatibility features (modulation format, bit-rate, etc…) Wavelength that can be handled by the device Need to get a new type of top TLV from IANA

12 draft-peloso-ccamp-wson-opsf-oeo-01 12 | OSPF-TE extensions for WSON | IETF 77th Conclusion This draft presents a solution to address the flooding of information through OSPF-TE to provide a graph that can be exploited to compute both the spatial and spectral assignment of a LSP into WSON. Next step: Get a CCAMP feedback on the content of this solution.

13 draft-peloso-ccamp-wson-opsf-oeo-01 13 | OSPF-TE extensions for WSON | IETF 77th Questions and discussion?

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