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Deep-Learning-Based Koopman Modeling for Online Control Synthesis of Nonlinear Power System Transient Dynamics

Tianqiao Zhao, Meng Yue, Jianhui Wang

2023IEEE Transactions on Industrial Informatics32 citationsDOIOpen Access PDF

Abstract

Power system stability and control have become more challenging due to the increasing uncertainty associated with renewable generation. The performance of conventional control is highly driven by the physics-based offline-developed dynamic models that can deviate from the actual system characteristics under different operating conditions and/or configurations. Data-driven approaches based on online measurements can be a better solution to addressing these issues by capturing real-time operation conditions. This article describes a novel fully data-driven probabilistic framework to derive a linear representation of postcontingency grid dynamics and online prescribe control based on the derived model to enhance transient stability. The complex nonlinear power system dynamics is approximated by a linear model by using multiple neural network modules that infer distributions of the observations and introducing a Koopman layer to sample possible Koopman linear models from the inferred distributions. The trained model features linearity that can be easily incorporated into the existing linear control design paradigm and ease the controller design process. The effectiveness of Koopman-based control designs is validated through comparative case studies, which demonstrate increased prediction accuracy and control performance when applied to a power system with heterogeneous generator dynamics.

Topics & Concepts

Control theory (sociology)Computer scienceTransient (computer programming)System dynamicsNonlinear systemControl engineeringController (irrigation)Stability (learning theory)Electric power systemRepresentation (politics)Probabilistic logicArtificial neural networkPower (physics)Artificial intelligenceEngineeringMachine learningControl (management)Operating systemPhysicsPolitical scienceLawAgronomyPoliticsQuantum mechanicsBiologyModel Reduction and Neural NetworksPower System Optimization and StabilityFluid Dynamics and Vibration Analysis
Deep-Learning-Based Koopman Modeling for Online Control Synthesis of Nonlinear Power System Transient Dynamics | Litcius