Litcius/Paper detail

Deep Reinforcement Learning-Based Model-Free On-Line Dynamic Multi-Microgrid Formation to Enhance Resilience

Jin Zhao, Fangxing Li, Srijib Mukherjee, Christopher Sticht

2022IEEE Transactions on Smart Grid133 citationsDOIOpen Access PDF

Abstract

Multi-microgrid formation (MMGF) is a promising solution for enhancing power system resilience. This paper proposes a new deep reinforcement learning (RL) based model-free on-line dynamic MMGF scheme. The dynamic MMGF problem is formulated as a Markov decision process, and a complete deep RL framework is specially designed for the topology-transformable micro-grids. In order to reduce the large action space caused by flexible switch operations, a topology transformation method is proposed and an action-decoupling Q-value is applied. Then, a convolutional neural network (CNN) based multi-buffer double deep Q-network (CM-DDQN) is developed to further improve the learning ability of the original DQN method. The proposed deep RL method provides real-time computing to support the on-line dynamic MMGF scheme, and the scheme handles a long-term resilience enhancement problem using an adaptive on-line MMGF to defend changeable conditions. The effectiveness of the proposed method is validated using a 7-bus system and the IEEE 123-bus system. The results show strong learning ability, timely response for varying system conditions and convincing resilience enhancement.

Topics & Concepts

MicrogridReinforcement learningComputer scienceMarkov decision processResilience (materials science)Electric power systemDeep learningDecoupling (probability)Scheme (mathematics)Network topologyArtificial intelligenceQ-learningConvolutional neural networkTopology (electrical circuits)Markov processDistributed computingPower (physics)Control engineeringEngineeringControl (management)MathematicsComputer networkElectrical engineeringThermodynamicsMathematical analysisStatisticsPhysicsQuantum mechanicsMicrogrid Control and OptimizationOptimal Power Flow DistributionIslanding Detection in Power Systems