Litcius/Paper detail

Topology-Aware Graph Neural Network-Based State Estimation for PMU-Unobservable Power Systems

Shiva Moshtagh, Behrouz Azimian, Mohammad Golgol, Anamitra Pal

2025IEEE Transactions on Power Systems14 citationsDOI

Abstract

Traditional optimization-based techniques for <italic xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">time-synchronized</i> state estimation (SE) often suffer from high online computational burden, limited phasor measurement unit (PMU) coverage, and presence of non-Gaussian measurement noise. Although conventional learning-based models have been developed to overcome these challenges, they are negatively impacted by topology changes and real-time data loss. This paper proposes a novel deep geometric learning approach based on graph neural networks (GNNs) to estimate the states of PMU-unobservable power systems. The proposed approach combines graph convolution and multi-head graph attention layers inside a customized end-to-end learning framework to handle topology changes and real-time data loss. An upper bound on SE error as a function of topology change is also derived. Experimental results for different test systems demonstrate superiority of the proposed customized GNN-SE (CGNN-SE) over traditional optimization-based techniques as well as conventional learning-based models in presence of topology changes, PMU failures, bad data, non-Gaussian measurement noise, and large system implementation.

Topics & Concepts

UnobservableNetwork topologyTopology (electrical circuits)Artificial neural networkElectric power systemComputer scienceGraphObservabilityEstimationGraph theoryPower networkPower (physics)MathematicsArtificial intelligenceEngineeringTheoretical computer scienceEconometricsComputer networkElectrical engineeringSystems engineeringPhysicsApplied mathematicsQuantum mechanicsCombinatoricsPower System Optimization and StabilitySmart Grid and Power SystemsPower Systems and Renewable Energy