强化学习
可扩展性
计算机科学
稳健性(进化)
电力系统
网格
趋同(经济学)
模型预测控制
控制工程
控制理论(社会学)
工程类
控制(管理)
功率(物理)
人工智能
几何学
化学
数据库
量子力学
经济
基因
生物化学
物理
数学
经济增长
作者
Renke Huang,Yujiao Chen,Tianzhixi Yin,Xinya Li,Ang Li,Jie Tan,Wenhao Yu,Yuan Liu,Qiuhua Huang
标识
DOI:10.1109/tpwrs.2021.3095179
摘要
Load shedding has been one of the most widely used and effective emergency control approaches against voltage instability. With increased uncertainties and rapidly changing operational conditions in power systems, existing methods have outstanding issues in terms of either speed, adaptiveness, or scalability. Deep reinforcement learning (DRL) was regarded and adopted as a promising approach for fast and adaptive grid stability control in recent years. However, existing DRL algorithms show two outstanding issues when being applied to power system control problems: 1) computational inefficiency that requires extensive training and tuning time; and 2) poor scalability making it difficult to scale to high dimensional control problems. To overcome these issues, an novel derivative-free DRL algorithm named PARS was developed and tailored for power system voltage stability control via load shedding. The method was tested on both the IEEE 39-bus and IEEE 300-bus systems, and the latter is by far the largest scale for such a study. Test results show that, compared to other methods including model-predictive control (MPC) and proximal policy optimization(PPO) methods, PARS shows better computational efficiency (faster convergence), more robustness in learning, excellent scalability and generalization capability.
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