Wavelength routed optical networks allow to design a logical topology, comprising lightpaths and routers, which is overlayed on the physical topology, comprising optical fibers and optical cross-connects, by solving a routing and wavelength assignment (RWA) problem. In this paper we extend the concept of lightpath to the one of super-lightpath, which uses a simple bit level time division multiplexing that can be directly implemented in the optical domain, to split the wavelength bandwidth among more than one traffic flow. This allows to design logical topologies with an increased number of logical links, thus reducing the average distance among nodes, i.e., the number of electro-optic and opto-electronic conversions, and the traffic congestion on logical links. At the same time, this reduces the number of wavelengths required to solve the RWA problem. Being the super-lightpath RWA problem computationally intractable, we propose two heuristics which show that the number of wavelengths required to overlay the same logical topology on the same physical topology is reduced by more that 65% using super-lightpaths.

Exploiting OTDM technology in WDM networks / Mellia, Marco; Leonardi, Emilio; Feletig, M.; Gaudino, Roberto; Neri, Fabio. - STAMPA. - 3:(2002), pp. 1822-1831. (Intervento presentato al convegno IEEE INFOCOM 2002, 21st annual joint conference of the IEEE Computer and Communications Societies tenutosi a Newe York (USA) nel 23-27 June 2002) [10.1109/INFCOM.2002.1019436].

Exploiting OTDM technology in WDM networks

MELLIA, Marco;LEONARDI, Emilio;GAUDINO, ROBERTO;NERI, Fabio
2002

Abstract

Wavelength routed optical networks allow to design a logical topology, comprising lightpaths and routers, which is overlayed on the physical topology, comprising optical fibers and optical cross-connects, by solving a routing and wavelength assignment (RWA) problem. In this paper we extend the concept of lightpath to the one of super-lightpath, which uses a simple bit level time division multiplexing that can be directly implemented in the optical domain, to split the wavelength bandwidth among more than one traffic flow. This allows to design logical topologies with an increased number of logical links, thus reducing the average distance among nodes, i.e., the number of electro-optic and opto-electronic conversions, and the traffic congestion on logical links. At the same time, this reduces the number of wavelengths required to solve the RWA problem. Being the super-lightpath RWA problem computationally intractable, we propose two heuristics which show that the number of wavelengths required to overlay the same logical topology on the same physical topology is reduced by more that 65% using super-lightpaths.
2002
0780374762
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11583/1412070
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