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Distribution System Resilience Under Asynchronous Information Using Deep Reinforcement Learning

Juan Carlos Bedoya, Yübo Wang, Chen‐Ching Liu

2021IEEE Transactions on Power Systems52 citationsDOI

Abstract

Resilience of a distribution system can be enhanced by efficient restoration of critical load following a major outage. Existing models include optimization approaches that consider available information without incorporating the inherent asynchrony of data arrival during execution of the restoration plan. Failure to consider the asynchronous nature of information arrival can lead to underutilization of critical resources. Moreover, analytical models become computationally inefficient for large scale systems. On the other hand, artificial intelligence (AI)-based tools have demonstrated efficient results for power system applications. In this paper, it is proposed a Reinforcement Learning (RL) model that learns how to efficiently restore a distribution system after a major outage. The proposed approach is based on a Monte Carlo Tree Search to expedite the training process. The proposed model strategy provides a robust decision-making tool for asynchronous and partial information scenarios. The results, validated with the IEEE 13-bus test feeder and IEEE 8500-node distribution test feeder, demonstrate the effectiveness and scalability of the proposed method.

Topics & Concepts

Reinforcement learningComputer scienceScalabilityAsynchronous communicationAsynchrony (computer programming)Resilience (materials science)Electric power systemDistributed computingNode (physics)Artificial intelligencePower (physics)EngineeringComputer networkDatabaseStructural engineeringThermodynamicsQuantum mechanicsPhysicsOptimal Power Flow DistributionSmart Grid Security and ResiliencePower System Optimization and Stability