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Deep Neural Networks in Power Systems: A Review

Mahdi Khodayar, Jacob Regan

2023Energies33 citationsDOIOpen Access PDF

Abstract

Identifying statistical trends for a wide range of practical power system applications, including sustainable energy forecasting, demand response, energy decomposition, and state estimation, is regarded as a significant task given the rapid expansion of power system measurements in terms of scale and complexity. In the last decade, deep learning has arisen as a new kind of artificial intelligence technique that expresses power grid datasets via an extensive hypothesis space, resulting in an outstanding performance in comparison with the majority of recent algorithms. This paper investigates the theoretical benefits of deep data representation in the study of power networks. We examine deep learning techniques described and deployed in a variety of supervised, unsupervised, and reinforcement learning scenarios. We explore different scenarios in which discriminative deep frameworks, such as Stacked Autoencoder networks and Convolution Networks, and generative deep architectures, including Deep Belief Networks and Variational Autoencoders, solve problems. This study’s empirical and theoretical evaluation of deep learning encourages long-term studies on improving this modern category of methods to accomplish substantial advancements in the future of electrical systems.

Topics & Concepts

Deep learningArtificial intelligenceComputer scienceAutoencoderMachine learningDeep belief networkReinforcement learningDiscriminative modelArtificial neural networkVariety (cybernetics)Electric power systemPower (physics)Quantum mechanicsPhysicsEnergy Load and Power ForecastingSolar Radiation and PhotovoltaicsPower System Optimization and Stability
Deep Neural Networks in Power Systems: A Review | Litcius