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Optimal Policy Characterization Enhanced Actor-Critic Approach for Electric Vehicle Charging Scheduling in a Power Distribution Network

Jiangliang Jin, Yunjian Xu

2020IEEE Transactions on Smart Grid112 citationsDOI

Abstract

We study the scheduling of large-scale electric vehicle (EV) charging in a power distribution network under random renewable generation and electricity prices. The problem is formulated as a stochastic dynamic program with unknown state transition probability. To mitigate the curse of dimensionality, we establish the nodal multi-target (NMT) characterization of the optimal scheduling policy: all EVs with the same deadline at the same bus should be charged to approach a single target of remaining energy demand. We prove that the NMT characterization is optimal under arbitrarily random system dynamics. To adaptively learn the dynamics of system uncertainty, we propose a model-free soft-actor-critic (SAC) based method to determine the target levels for the characterized NMT policy. The proposed SAC + NMT approach significantly outperforms existing deep reinforcement learning methods (in our numerical experiments on the IEEE 37-node test feeder), as the established NMT characterization sharply reduces the dimensionality of neural network outputs without loss of optimality.

Topics & Concepts

Curse of dimensionalityScheduling (production processes)Computer scienceMathematical optimizationElectric vehicleReinforcement learningDynamic programmingArtificial neural networkDynamic priority schedulingElectric power systemVehicle dynamicsPower (physics)EngineeringAlgorithmMathematicsArtificial intelligenceAutomotive engineeringTelecommunicationsQuality of serviceQuantum mechanicsPhysicsElectric Vehicles and InfrastructureSmart Grid Energy ManagementMicrogrid Control and Optimization