微电网
强化学习
计算机科学
马尔可夫决策过程
弹性(材料科学)
电力系统
深度学习
解耦(概率)
方案(数学)
网络拓扑
人工智能
增强学习
卷积神经网络
拓扑(电路)
马尔可夫过程
分布式计算
功率(物理)
控制工程
工程类
控制(管理)
数学
计算机网络
电气工程
热力学
数学分析
统计
物理
量子力学
作者
Jin Zhao,Fangxing Li,Srijib Mukherjee,Christopher Sticht
标识
DOI:10.1109/tsg.2022.3160387
摘要
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. Additionally, the dynamic MMGF problem is formulated as a Markov decision process, and a complete deep RL framework is specially designed for the topologytransformable 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.
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