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Topology-Transferable Physics-Guided Graph Neural Network for Real-Time Optimal Power Flow

Mei Yang, Gao Qiu, Junyong Liu, Youbo Liu, Tingjian Liu, Zhiyuan Tang, Lijie Ding, Yue Shui, Kai Liu

2024IEEE Transactions on Industrial Informatics26 citationsDOI

Abstract

Larger-scale stochastic power systems urge the development of real-time alternating current optimal power flow, artificial intelligence (AI) thus becomes an alternative. However, traditional AI only imitates experiences, and cannot follow in-depth physics. This may cause an undesired nongeneralizability and topology intractability. To address this issue, a physics-guided graph neutral network (PG-GNN) is proposed. The PG-GNN firstly capture the physical constraints by a dual Lagrangian. Besides, the branch features of power grids are fully exploited to allow the PG-GNN to master tremendous topological patterns. To further manage the out-of-distribution topology, stability property of the PG-GNN is proved, then upon this evidence, an online transfer learning is proposed to allow the PG-GNN to fast master the unexpected topology. Numerical tests on benchmarks show that, the proposed method holds well topology-transferability, enables near or even better solutions than conventional optimizer, but merits much more than 100 times efficiency.

Topics & Concepts

Topology (electrical circuits)Network topologyComputer scienceGraphTransferabilityArtificial neural networkTheoretical computer scienceArtificial intelligenceEngineeringMachine learningElectrical engineeringComputer networkLogitAdvanced Graph Neural NetworksOptimal Power Flow DistributionPower System Optimization and Stability
Topology-Transferable Physics-Guided Graph Neural Network for Real-Time Optimal Power Flow | Litcius