Replicator dynamics for distributed Inter-Cell Interference Coordination

In order to achieve high data rates in future wireless packet switched cellular networks, aggressive frequency reuse is inevitable due to the scarcity of the radio resources. While intra-cell interference is mostly mitigated and can be ignored, inter-cell interference can severely degrade performances with bad channel quality. Hence, Inter-Cell Interference Coordination (ICIC) is commonly identified as a key radio resource management mechanism to enhance system performance of 4G networks. This paper addresses the problem of ICIC in the downlink of Long Term Evolution (LTE) systems where the resource selection process is apprehended as a potential game. Proving the existence of Nash Equilibriums (NE) shows that stable resource allocations can be reached by selfish Base Stations (BS). We put forward a fully decentralized algorithm based on replicator dynamics to attain the pure NEs of the modeled game. Each BS will endeavor to select a set of favorable resources with low interference based on local knowledge only making use of signaling messages already present in the downlink of LTE systems.

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