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Optimized Power and Cell Individual Offset for Cellular Load Balancing via Reinforcement Learning

Ghada Alsuhli, Karim Banawan, Karim G. Seddik, Ayman Elezabi

202120 citationsDOI

Abstract

We consider the problem of jointly optimizing the transmission power and cell individual offsets (CIOs) in the downlink of cellular networks using reinforcement learning. To that end, we reformulate the problem as a Markov decision process (MDP). We abstract the cellular network as a state, which comprises of carefully selected key performance indicators (KPIs). We present a novel reward function, namely, the penalized throughput, to reflect the tradeoff between the total throughput of the network and the number of covered users. We employ the twin deep delayed deterministic policy gradient (TD3) technique to learn how to maximize the proposed reward function through the interaction with the cellular network. We assess the proposed technique by simulating an actual cellular network, whose parameters and base station placement are derived from a 4G network operator, using NS-3 and SUMO simulators. Our results show the following: 1) optimizing one of the controls is significantly inferior to jointly optimizing both controls; 2) our proposed technique achieves 18.4% throughput gain compared with the baseline of fixed transmission power and zero CIOs; 3) there is a tradeoff between the total throughput of the network and the number of covered users.

Topics & Concepts

Computer scienceReinforcement learningCellular networkThroughputOffset (computer science)Markov decision processBase stationNetwork performanceTelecommunications linkMarkov processTransmission (telecommunications)Markov chainMathematical optimizationComputer networkArtificial intelligenceWirelessMachine learningTelecommunicationsMathematicsProgramming languageStatisticsAdvanced MIMO Systems OptimizationAdvanced Wireless Network OptimizationCooperative Communication and Network Coding