Multicast routing and wavelength assignment in multihop optical networks
IEEE/ACM Transactions on Networking (TON)
Multicast Routing and Wavelength Assignment in Multi-Hop Optical Networks
ICN '01 Proceedings of the First International Conference on Networking-Part 1
Multicast connection capacity of WDM switching networks with limited wavelength conversion
IEEE/ACM Transactions on Networking (TON)
Multicast connection capacity of WDM switching networks without wavelength conversion
MMACTE'05 Proceedings of the 7th WSEAS International Conference on Mathematical Methods and Computational Techniques In Electrical Engineering
New algorithms for multicast routing and wavelength assignment in multi-hop optical WDM networks
Photonic Network Communications
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A local lightwave network can be constructed by employing two-way fibers to connect nodes in a passive-star physical topology, and the available optical bandwidth may be effectively accessed by the nodal transmitters and receivers at electronic rates using wavelength division multiplexing (WDM). The number of channels, ω, in a WDM network is limited by technology and is usually less than the number of nodes, N, in the network. We provide a general method using channel sharing to construct practical multi-hop networks under this limitation. Channel sharing may be achieved through time division multiplexing. The method is applied to a generalized shuffle-exchange-based multi-hop architecture, called GEMNET. Multicasting-the ability to transmit information from a single source node to multiple destination nodes-is becoming an important requirement in high-performance networks. Multicasting, if improperly implemented, can be bandwidth-abusive. Channel sharing is one approach toward efficient management of multicast traffic. We develop a general modeling procedure for the analysis of multicast (point-to-multipoint) traffic in shared-channel, multihop WDM networks. The analysis is comprehensive in that it considers all components of delay that packets in the network experience-namely, synchronization, queuing, transmission, and propagation. The results show that, in the presence of multicast traffic, WDM networks with ω