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Physics-Informed Deep Neural Network Method for Limited Observability State Estimation

Jonathan Ostrometzky, Konstantin Berestizshevsky, Andrey Bernstein, Gil Zussman

202036 citationsDOIOpen Access PDF

Abstract

The precise knowledge regarding the state of the power grid is important in order to ensure optimal and reliable grid operation. Specifically, knowing the state of the distribution grid becomes increasingly important as more renewable energy sources are connected directly into the distribution network, increasing the fluctuations of the injected power. In this paper, we consider the case when the distribution grid becomes partially observable, due to for example cyber attacks, and the state estimation problem is under-determined. We present a new methodology that leverages a deep neural network (DNN) to estimate the grid state. The standard DNN training method is modified to explicitly incorporate the physical information of the grid topology and line/shunt admittance. We show that our method leads to a superior accuracy of the estimation when compared to the case when no physical information is provided. Finally, we compare the performance of our method to the standard state estimation approach, which is based on the weighted least squares with pseudo-measurements, and show that our method performs significantly better with respect to the estimation accuracy.

Topics & Concepts

ObservabilityComputer scienceGridArtificial neural networkObservableState (computer science)Smart gridTopology (electrical circuits)Mathematical optimizationArtificial intelligenceAlgorithmMathematicsEngineeringApplied mathematicsGeometryElectrical engineeringCombinatoricsPhysicsQuantum mechanicsPower System Optimization and StabilityOptimal Power Flow DistributionModel Reduction and Neural Networks