Machine Learning for Scalable and Optimal Load Shedding Under Power System Contingency

IF 7.2 1区工程技术 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Transactions on Power Systems Pub Date : 2025-01-13 DOI:10.1109/TPWRS.2025.3528434

Yuqi Zhou;Hao Zhu

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Abstract

Prompt and effective corrective actions in response to unexpected contingencies are crucial for improving power system resilience and preventing cascading blackouts. The optimal load shedding (OLS) accounting for network limits has the potential to address the diverse system-wide impacts of contingency scenarios as compared to traditional local schemes. However, due to the fast cascading propagation of initial contingencies, real-time OLS solutions are challenging to attain in large systems with high computation and communication needs. In this paper, we propose a decentralized design that leverages offline training of a neural network (NN) model for individual load centers to autonomously construct the OLS solutions from locally available measurements. Our learning-for-OLS approach can greatly reduce the computation and communication needs during online emergency responses, thus preventing the cascading propagation of contingencies for enhanced power grid resilience. Numerical studies on both the IEEE 118-bus system and a synthetic Texas 2000-bus system have demonstrated the efficiency and effectiveness of our scalable OLS learning design for timely power system emergency operations.

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电力系统突发事件下可扩展最优减载的机器学习

针对突发事件采取及时有效的纠正措施对于提高电力系统的恢复能力和防止级联停电至关重要。与传统的局部方案相比，考虑网络限制的最佳减载（OLS）有可能解决突发情况对整个系统的各种影响。然而，由于初始突发事件的快速级联传播，在具有高计算和通信需求的大型系统中实现实时OLS解决方案具有挑战性。在本文中，我们提出了一种分散的设计，它利用单个负载中心的神经网络（NN）模型的离线训练，从本地可用的测量数据中自主构建OLS解决方案。我们的ols学习方法可以大大减少在线应急响应过程中的计算和通信需求，从而防止突发事件的级联传播，增强电网的弹性。对IEEE 118总线系统和综合德克萨斯2000总线系统的数值研究表明，我们的可扩展OLS学习设计在电力系统及时应急运行中的效率和有效性。

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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来源期刊

IEEE Transactions on Power Systems 工程技术-工程：电子与电气

CiteScore

15.80

自引率

7.60%

发文量

696

审稿时长

3 months

期刊介绍： The scope of IEEE Transactions on Power Systems covers the education, analysis, operation, planning, and economics of electric generation, transmission, and distribution systems for general industrial, commercial, public, and domestic consumption, including the interaction with multi-energy carriers. The focus of this transactions is the power system from a systems viewpoint instead of components of the system. It has five (5) key areas within its scope with several technical topics within each area. These areas are: (1) Power Engineering Education, (2) Power System Analysis, Computing, and Economics, (3) Power System Dynamic Performance, (4) Power System Operations, and (5) Power System Planning and Implementation.