Abstract EN:

The migration from ring to arbitrary mesh topologies and from static to dynamic traffic in optical networks gives rise to increased complexity. To reduce the size and complexity of OXCs, the optical granularity or optical grooming is introduced. This grooming concept is extended to create hierarchical levels of grooming in the optical as well as in the electronic domain. This way we can create what is called multi-granular optical network characterized by different scales of differentiation in the switching operations. This multi-granular optical network creates a compromise between hardware and operational complexity. New optimization and network dimensioning problems arise to control and design the multi-granular or hierarchical optical cross-connects (MG-OXC or HXC). In this thesis, we model first the multi-granular network using a novel Multi-Granularity Graph Model (MGGM). We then propose an MG-OXC (or HXC) analytical model to analyze the intrinsic operational complexity of an MG-OXC before studying its behavior in an optical network. We then propose a wavelength rearrangement to optimize, when it is possible, the state of a multi-granular optical network with a minimum of information to broadcast all along the network. Finally, we consider the dynamic traffic context where the problem is to know when to proceed with demultiplexing/multiplexing to use finer and finer granularities at each node for a given demand