基于模型的配电网主动调度安全强化学习

IF 8.6 1区工程技术 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Smart Grid Pub Date : 2025-03-17 DOI:10.1109/TSG.2025.3547843

Yuxiang Guan;Wenhao Ma;Liang Che;Mohammad Shahidehpour

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引用次数: 0

摘要

数据驱动的方法，特别是强化学习（RL），擅长处理不确定性，但在确保安全性方面很差，这是主动配电网络（DNs）的关键要求。为了解决主动DN调度问题和克服RL最关键的缺陷—安全风险，本文提出了一个基于模型的安全RL框架，该框架在RL的环路中嵌入了一个基于模型的安全模块（MBSM）。该框架可以保证agent的行为（可控分布式能源的实/无功输出）严格满足DN的运行安全约束。它不依赖于任何专业知识，适合于大规模系统的应用。通过与现有的安全RL （Safe RL）和经典优化方法的对比研究，验证了该方法在严格满足DN运行安全约束的情况下，在DERs运行成本和可再生能源消耗方面达到了最佳性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Model-Based Safe Reinforcement Learning for Active Distribution Network Scheduling

Data-driven methods, especially reinforcement learning (RL), are adept at addressing uncertainties but are poor at ensuring safety, which is a critical requirement in active distribution networks (DNs). To address the problem of active DN scheduling and to overcome RL’ most critical drawback—security risk, this paper proposes a model-based safe RL framework that embeds a model-based safety module (MBSM) in the RL’s loop. The proposed framework can guarantee that the agent’s actions (real/reactive power outputs of controllable distributed energy resources (DERs)) strictly satisfy the DN’s operational security constraints. It does not rely on any expert knowledge and is suitable for application in large-scale systems. Comparative studies against existing Safe RL (SRL) and classic optimization methods verify that the proposed method achieves the best performance in terms of DERs operating cost and renewable energy consumption while strictly satisfying the DN’s operational security constraints.

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来源期刊

IEEE Transactions on Smart Grid ENGINEERING, ELECTRICAL & ELECTRONIC-

CiteScore

22.10

自引率

9.40%

发文量

526

审稿时长

6 months

期刊介绍： The IEEE Transactions on Smart Grid is a multidisciplinary journal that focuses on research and development in the field of smart grid technology. It covers various aspects of the smart grid, including energy networks, prosumers (consumers who also produce energy), electric transportation, distributed energy resources, and communications. The journal also addresses the integration of microgrids and active distribution networks with transmission systems. It publishes original research on smart grid theories and principles, including technologies and systems for demand response, Advance Metering Infrastructure, cyber-physical systems, multi-energy systems, transactive energy, data analytics, and electric vehicle integration. Additionally, the journal considers surveys of existing work on the smart grid that propose new perspectives on the history and future of intelligent and active grids.