Litcius/Paper detail

Power-grid stability predictions using transferable machine learning

Seong-Gyu Yang, Beom Jun Kim, Seung‐Woo Son, Heetae Kim

2021Chaos An Interdisciplinary Journal of Nonlinear Science20 citationsDOIOpen Access PDF

Abstract

Complex network analyses have provided clues to improve power-grid stability with the help of numerical models. The high computational cost of numerical simulations, however, has inhibited the approach, especially when it deals with the dynamic properties of power grids such as frequency synchronization. In this study, we investigate machine learning techniques to estimate the stability of power-grid synchronization. We test three different machine learning algorithms-random forest, support vector machine, and artificial neural network-training them with two different types of synthetic power grids consisting of homogeneous and heterogeneous input-power distribution, respectively. We find that the three machine learning models better predict the synchronization stability of power-grid nodes when they are trained with the heterogeneous input-power distribution rather than the homogeneous one. With the real-world power grids of Great Britain, Spain, France, and Germany, we also demonstrate that the machine learning algorithms trained on synthetic power grids are transferable to the stability prediction of the real-world power grids, which implies the prospective applicability of machine learning techniques on power-grid studies.

Topics & Concepts

Stability (learning theory)Computer scienceArtificial neural networkSupport vector machinePower (physics)Synchronization (alternating current)GridArtificial intelligenceElectric power systemMachine learningMathematicsTelecommunicationsPhysicsQuantum mechanicsChannel (broadcasting)GeometryPower System Optimization and StabilityNonlinear Dynamics and Pattern FormationNeural Networks and Reservoir Computing