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Physics-guided Deep Learning for Power System State Estimation

Lei Wang, Wei Sun, Shuangshuang Jin

2020Journal of Modern Power Systems and Clean Energy88 citationsDOIOpen Access PDF

Abstract

In the past decade, dramatic progress has been made in the field of machine learning. This paper explores the possibility of applying deep learning in power system state estimation. Traditionally, physics-based models are used including weighted least square (WLS) or weighted least absolute value (WLAV). These models typically consider a single snapshot of the system without capturing temporal correlations of system states. In this paper, a physics-guided deep learning (PGDL) method is proposed. Specifically, inspired by autoencoders, deep neural networks (DNNs) are used to learn the temporal correlations. The estimated system states from DNNs are then checked against physics laws by running through a set of power flow equations. Hence, the proposed PGDL is both data-driven and physics-guided. The accuracy and robustness of the proposed PGDL method are compared with traditional methods in standard IEEE cases. Simulations show promising results and the applicability is further discussed.

Topics & Concepts

Robustness (evolution)Artificial neural networkDeep learningArtificial intelligenceDeep neural networksSnapshot (computer storage)PhysicsElectric power systemPower flowStatistical physicsMachine learningComputer sciencePower (physics)Quantum mechanicsBiochemistryGeneOperating systemChemistryEnergy Load and Power ForecastingPower System Optimization and StabilityPower System Reliability and Maintenance
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