基于图神经网络的高效最优潮流模型简化方法-电气工程与自动化-CSCIED科技核心评价数据库-手机版

基于图神经网络的高效最优潮流模型简化方法

An efficient optimal power flow model reduction method based on graph neural networks

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DOI	10.12208/j.jeea.20250106
刊名	电气工程与自动化 Journal of Electrical Engineering and Automation
年，卷(期)	2025, 4(4)
作者	胡松林¹, 黄煜¹, 李忠行¹, 王毅²,
作者单位	1 南京邮电大学碳中和先进技术研究院江苏南京 2 国网电力科学研究院有限公司（南瑞集团有限公司）江苏南京
摘要	针对大规模输电网络最优潮流（Optimal Power Flow, OPF）计算中存在的计算复杂、约束冗余等问题，提出一种基于图神经网络（Graph Neural Network, GNN）的高效最优潮流模型简化方法。首先，基于支路潮流计算结果和载流率阈值（如90%）定义关键支路，并构建包含节点特征、边特征与邻接矩阵的电网图结构数据；其次，训练GNN模型实现关键支路状态预测，识别电网中可能发生越限的支路集合；最后，以GNN预测得到的关键支路集合为基础，构建约束显著减少的简化最优潮流（Reduced Optimal Power Flow, ROPF）模型。以自建73节点输电网络为算例进行仿真分析，结果表明：GNN模型在90%载流率阈值下的关键支路预测误差仅为OPF的2.47%，ROPF求解时间较OPF缩短13.2%。
Abstract	Addressing the challenges of computational complexity and redundant constraints in Optimal Power Flow (OPF) calculations for large-scale transmission networks, this paper proposes an efficient OPF model simplification method based on Graph Neural Networks (GNNs). First, critical branches are defined based on branch power flow calculation results and current carrying capacity thresholds (e.g., 90%), and power grid graph-structured data including node features, edge features, and adjacency matrices are constructed. Second, a GNN model is trained to predict the states of critical branches, identifying the set of branches in the power grid that are likely to violate limits. Finally, based on the critical branch set predicted by the GNN, a Reduced Optimal Power Flow (ROPF) model with significantly fewer constraints is formulated. Simulation analysis is conducted using a self-built 73-node transmission network. Results show that under the 90% loading threshold, the prediction error of key branches using the GNN model is only 2.47% compared to the original OPF, and the solution time of ROPF is reduced by 13.2%.
关键词	最优潮流；图神经网络；关键支路；模型简化；载流率阈值
KeyWord	Optimal power flow; Graph neural network; Critical branches; Model reduction; Loading threshold
基金项目
页码	17-25

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引用本文

胡松林, 黄煜, 李忠行, 王毅. 基于图神经网络的高效最优潮流模型简化方法 [J]. 电气工程与自动化. 2025; 4; (4). 17 - 25.

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