A Distributed Routing Algorithm for ER-LSP Setup in MLPS Networks

Garige, Naga Siddhardha

01 April 2003

The rapid growth of the Internet, in the last few years, has generated a need to enhance the existing IP networks in the areas of availability, dependability and scalability in order to provide a mission critical networking environment. In contemporary IP networks, data packets are routed as a function of the destination address and a single metric such as hop-count or delay. This approach tends to cause message traffic to converge onto the same link, which significantly increases congestion and leads to unbalanced network resource utilization. One solution to this problem is provided by Traffic Engineering (TE), which uses, bandwidth guaranteed, Explicitly Routed Label Switched Paths (ER-LSPs). Due to the dramatic increase in the backbone speeds, current research focuses more on traffic engineering with LSPs for clear control over the traffic distribution in the network. However, the growing popularity of the Internet is driving the Internet Service Providers to adapt new technologies in order to support multiple classes of applications with different characteristics and performance requirements. Multi-Protocol Label Switching (MPLS), which was proposed by the IETF provides essential facilities for traffic engineering and reliable QoS services for the Internet. MPLS networks provide the required flexibility for operators to manage their traffic with ER-LSPs. Even though conventional routing algorithms support the ER-LSP setup in MPLS networks, they are not efficient in link residual capacity information updates and limit resource utilization, which eventually leads to LSP failures and unbalanced network resource utilization. This thesis proposes a new architecture with a cluster based distributed routing algorithm to setup bandwidth guaranteed ER-LSPs in MPLS backbone networks. The proposed routing algorithm confines the route discovery region in order to reduce the routing overhead and computes all possible routes from ingress node to egress node. Based on LSP requirements and network load conditions, the egress node selects the most suitable path from the available paths in order to setup the LSP. This routing scheme optimizes network resource utilization by evenly distributing traffic throughout the network. The Resource Reservation Protocol (RSVP) works in conjunction with the routing protocol for resource reservation and label distribution along the LSP.

overlay model

traffic engineering

explicit routing

RSVP

network optimization

American Studies

Arts and Humanities

Arquitetura e prototipação de uma UNI optica para a rede GIGA / Architecture and prototype of an optical UNI for the GIGA network

Pasquini, Rafael

28 July 2006

Orientador: Mauricio Ferreira Magalhães / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Eletrica e de Computação / Made available in DSpace on 2018-08-07T06:05:16Z (GMT). No. of bitstreams: 1 Pasquini_Rafael_M.pdf: 1288391 bytes, checksum: d665dda186325e7c2231e9ee9be754be (MD5) Previous issue date: 2006 / Resumo: Os principais interesses do Projeto GIGA são o desenvolvimento de Tecnologias de Redes Ópticas, Serviços e Aplicações de Rede, Serviços Experimentais de Telecomunicações e Aplicações Científicas. No contexto deste Projeto, nosso grupo de pesquisa tem trabalhado no desenvolvimento de um Plano de Controle IP/WDM para integrar a Rede Cliente IP/MPLS com a Rede Óptica de Transporte WDM, de acordo com as especificações GMPLS e ASON. Especificamente neste trabalho é proposta uma Arquitetura para a UNI (User Network Interface) independente de protocolo de sinalização para prover a integralização entre as Redes Cliente e a Rede Óptica de Transporte. A Arquitetura da UNI proposta neste trabalho mantém inalterada a semântica de sinalização das redes cliente e de transporte da rede de testes do Projeto GIGA. Esta dissertação descreve como a Arquitetura desenvolvida suporta a independência quanto ao protocolo de sinalização e apresenta o protótipo implementado para validar a Arquitetura proposta / Abstract: The main interests of the GIGA Project are the deployment of Optical Network Technology, Network Services and Applications, Experimental Telecommunication Services and Scientific Applications. In the context of this Project, our research group has been working on the design of an IP/WDMControl Plane to integrate the IP/MPLS Client Network with the Optical Transport Network (WDM), according to the GMPLS and ASON specifications. Specifically in this work is proposed a signaling protocol independent UNI (User Network Interface) architecture to integrate the Client and the Optical Transport Networks. The proposed UNI architecture maintains unchanged the client and transport networks signaling semantics for the GIGA testbed network. This dissertation describes how the designed architecture supports the independence of the signaling protocol and presents the prototype implemented to validate the architecture / Mestrado / Engenharia de Computação / Mestre em Engenharia Elétrica

Comunicações óticas

Redes de computadores - Protocolos

Engenharia de tráfego

GMPLS

Optical networks

UNI

Overlay model

Signaling protocols

A distributed routing algorithm for ER-LSP setup in MLPS networks [electronic resource] / by Naga Siddhardha Garige.

Garige, Naga Siddhardha.

January 2003

Title from PDF of title page. / Document formatted into pages; contains 62 pages. / Thesis (M.S.E.E.)--University of South Florida, 2003. / Includes bibliographical references. / Text (Electronic thesis) in PDF format. / ABSTRACT: The rapid growth of the Internet, in the last few years, has generated a need to enhance the existing IP networks in the areas of availability, dependability and scalability in order to provide a mission critical networking environment. In contemporary IP networks, data packets are routed as a function of the destination address and a single metric such as hop-count or delay. This approach tends to cause message traffic to converge onto the same link, which significantly increases congestion and leads to unbalanced network resource utilization. One solution to this problem is provided by Traffic Engineering (TE), which uses, bandwidth guaranteed, Explicitly Routed Label Switched Paths (ER-LSPs). Due to the dramatic increase in the backbone speeds, current research focuses more on traffic engineering with LSPs for clear control over the traffic distribution in the network. / ABSTRACT: However, the growing popularity of the Internet is driving the Internet Service Providers to adapt new technologies in order to support multiple classes of applications with different characteristics and performance requirements. Multi-Protocol Label Switching (MPLS), which was proposed by the IETF provides essential facilities for traffic engineering and reliable QoS services for the Internet. MPLS networks provide the required flexibility for operators to manage their traffic with ER-LSPs. Even though conventional routing algorithms support the ER-LSP setup in MPLS networks, they are not efficient in link residual capacity information updates and limit resource utilization, which eventually leads to LSP failures and unbalanced network resource utilization. This thesis proposes a new architecture with a cluster based distributed routing algorithm to setup bandwidth guaranteed ER-LSPs in MPLS backbone networks. / ABSTRACT: The proposed routing algorithm confines the route discovery region in order to reduce the routing overhead and computes all possible routes from ingress node to egress node. Based on LSP requirements and network load conditions, the egress node selects the most suitable path from the available paths in order to setup the LSP. This routing scheme optimizes network resource utilization by evenly distributing traffic throughout the network. The Resource Reservation Protocol (RSVP) works in conjunction with the routing protocol for resource reservation and label distribution along the LSP. / System requirements: World Wide Web browser and PDF reader. / Mode of access: World Wide Web.

MPLS standard.

Packet switching (Data transmission).

Computer algorithms.

Routers (Computer networks)

rsvp.

explicit routing.

traffic engineering.

network optimization.

overlay model.