PLR-based heuristic for backup path computation in MPLS networks

To ensure service continuity in networks, local protection pre-configuring the backup paths is preferred to global protection. Under the practical hypothesis of single physical failures in the network, the backup paths which protect against different logical failure risks (node, link and shared risk...

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Veröffentlicht in:	Computer networks (Amsterdam, Netherlands : 1999) Netherlands : 1999), 2009-06, Vol.53 (9), p.1467-1479
Hauptverfasser:	Saidi, Mohand Yazid, Cousin, Bernard, Le Roux, Jean-Louis
Format:	Artikel
Sprache:	eng
Schlagworte:	Access methods and protocols, osi model Applied sciences Backup LSP Bandwidth sharing Bandwidths Computer networks Computer Science Computer simulation Exact sciences and technology Failure risk Heuristic Local protection Miscellaneous MPLS Network Networking and Internet Architecture Organization, operation and development plans Path computation Radiocommunications Recovery Scalability SRLG Studies Telecommunications Telecommunications and information theory Teleprocessing networks. Isdn
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container_title	Computer networks (Amsterdam, Netherlands : 1999)
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creator	Saidi, Mohand Yazid Cousin, Bernard Le Roux, Jean-Louis
description	To ensure service continuity in networks, local protection pre-configuring the backup paths is preferred to global protection. Under the practical hypothesis of single physical failures in the network, the backup paths which protect against different logical failure risks (node, link and shared risk link group (SRLG)) cannot be active at the same time. Thus, sharing bandwidth between such backup paths is crucial to increase the bandwidth availability. In this article, we focus on the optimal on-line distributed computation of the bandwidth-guaranteed backup paths in MPLS networks. As the requests for connection establishment and release arrive dynamically without knowledge of future arrivals, we choose to use the on-line mode to avoid LSP reconfigurations. We also selected a distributed computation to offer scalability and decrease the LSP setup time. Finally, the optimization of bandwidth utilization can be achieved thanks to the flexibility of the path choice offered by MPLS and to the bandwidth sharing. For a good bandwidth sharing, the backup path computation entities (BPCEs) require the knowledge and maintenance of a great quantity of bandwidth information (e.g. non aggregated link information or per path information) which is undesirable in distributed environments. To get around this problem, we propose here a PLR (point of local repair)-based heuristic (PLRH) which aggregates and noticeably decreases the size of the bandwidth information advertised in the network while offering a high bandwidth sharing. PLRH permits an efficient computation of backup paths. It is scalable, easy to be deployed and balances equitably computations on the network nodes. Simulations show that with the transmission of a small quantity of aggregated information per link, the ratio of rejected backup paths is low and close to the optimum.
doi_str_mv	10.1016/j.comnet.2009.01.009
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Under the practical hypothesis of single physical failures in the network, the backup paths which protect against different logical failure risks (node, link and shared risk link group (SRLG)) cannot be active at the same time. Thus, sharing bandwidth between such backup paths is crucial to increase the bandwidth availability. In this article, we focus on the optimal on-line distributed computation of the bandwidth-guaranteed backup paths in MPLS networks. As the requests for connection establishment and release arrive dynamically without knowledge of future arrivals, we choose to use the on-line mode to avoid LSP reconfigurations. We also selected a distributed computation to offer scalability and decrease the LSP setup time. Finally, the optimization of bandwidth utilization can be achieved thanks to the flexibility of the path choice offered by MPLS and to the bandwidth sharing. For a good bandwidth sharing, the backup path computation entities (BPCEs) require the knowledge and maintenance of a great quantity of bandwidth information (e.g. non aggregated link information or per path information) which is undesirable in distributed environments. To get around this problem, we propose here a PLR (point of local repair)-based heuristic (PLRH) which aggregates and noticeably decreases the size of the bandwidth information advertised in the network while offering a high bandwidth sharing. PLRH permits an efficient computation of backup paths. It is scalable, easy to be deployed and balances equitably computations on the network nodes. Simulations show that with the transmission of a small quantity of aggregated information per link, the ratio of rejected backup paths is low and close to the optimum.</description><identifier>ISSN: 1389-1286</identifier><identifier>EISSN: 1872-7069</identifier><identifier>DOI: 10.1016/j.comnet.2009.01.009</identifier><language>eng</language><publisher>Kidlington: Elsevier B.V</publisher><subject>Access methods and protocols, osi model ; Applied sciences ; Backup LSP ; Bandwidth sharing ; Bandwidths ; Computer networks ; Computer Science ; Computer simulation ; Exact sciences and technology ; Failure risk ; Heuristic ; Local protection ; Miscellaneous ; MPLS ; Network ; Networking and Internet Architecture ; Organization, operation and development plans ; Path computation ; Radiocommunications ; Recovery ; Scalability ; SRLG ; Studies ; Telecommunications ; Telecommunications and information theory ; Teleprocessing networks. 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Under the practical hypothesis of single physical failures in the network, the backup paths which protect against different logical failure risks (node, link and shared risk link group (SRLG)) cannot be active at the same time. Thus, sharing bandwidth between such backup paths is crucial to increase the bandwidth availability. In this article, we focus on the optimal on-line distributed computation of the bandwidth-guaranteed backup paths in MPLS networks. As the requests for connection establishment and release arrive dynamically without knowledge of future arrivals, we choose to use the on-line mode to avoid LSP reconfigurations. We also selected a distributed computation to offer scalability and decrease the LSP setup time. Finally, the optimization of bandwidth utilization can be achieved thanks to the flexibility of the path choice offered by MPLS and to the bandwidth sharing. 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subjects	Access methods and protocols, osi model Applied sciences Backup LSP Bandwidth sharing Bandwidths Computer networks Computer Science Computer simulation Exact sciences and technology Failure risk Heuristic Local protection Miscellaneous MPLS Network Networking and Internet Architecture Organization, operation and development plans Path computation Radiocommunications Recovery Scalability SRLG Studies Telecommunications Telecommunications and information theory Teleprocessing networks. Isdn
title	PLR-based heuristic for backup path computation in MPLS networks
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