This paper studies the problem of light splitter placement (LSP) and wavelength converter placement (WCP) in all-optical WDM networks to enable optimal provisioning of static and dynamic traffic through efficient photonic multicast connections. To solve the LSP-WCP problem under static traffic provisioning, an Integer Linear Programming model is formulated to achieve the optimal solution in the sense that the total number of wavelength channels required by the multicast requests is minimized. To solve the LSP-WCP problem under dynamic traffic provisioning, a complementary-combined LSP-WCP heuristic is proposed to minimize the multicast traffic blocking probability, and is proved through extensive simulations.
Abstract-This paper presents the Photonic Interdomain Negotiator (PIN) as the secure global optical control plane architecture to interoperate multiple wavelength-routed network domains with incompatible local control planes. The PIN interdomain routing and wavelength assignment is characterized by constraint-based optical path-vector routing to determine endto-end lightpath across multiple domains, and by conversionaware wavelength discovery to resolve wavelength blocking during discovery phase. The PIN interdomain optical signaling is supported by the Robust Fast Optical Reservation Protocol (RFORP) to minimize reservation delay by employing parallel reservation processing in multiple domains along a domain-path, and to minimize wavelength blocking during reservation phase by employing localized rerouting.
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