Predicting basin stability of power grids using graph neural networks

Christian Nauck; Michael Lindner; Konstantin Schürholt; Haoming Zhang; Paul Schultz; Jürgen Kurths; Ingrid Isenhardt; Frank Hellmann

doi:10.1088/1367-2630/ac54c9

New Journal of Physics (Jan 2022)

Predicting basin stability of power grids using graph neural networks

Christian Nauck,
Michael Lindner,
Konstantin Schürholt,
Haoming Zhang,
Paul Schultz,
Jürgen Kurths,
Ingrid Isenhardt,
Frank Hellmann

Affiliations

Christian Nauck: Department of Complexity Science, Potsdam Institute for Climate Impact Research , Telegrafenberg A 31, Potsdam, Brandenburg 14473, Germany
Michael Lindner: Department of Complexity Science, Potsdam Institute for Climate Impact Research , Telegrafenberg A 31, Potsdam, Brandenburg 14473, Germany
Konstantin Schürholt: Institute of Computer Science, University of St. Gallen , Rosenbergstrasse 30, St. Gallen 9000, Switzerland
Haoming Zhang: Cybernetics Lab IMA & IfU, RWTH Aachen University , Dennewartstraße 27, Aachen 52068, Germany
Paul Schultz: 50Hertz Transmission GmbH, Elia Group , Heidestraße 2, Berlin 10557, Germany
Jürgen Kurths: Department of Complexity Science, Potsdam Institute for Climate Impact Research , Telegrafenberg A 31, Potsdam, Brandenburg 14473, Germany
Ingrid Isenhardt: Cybernetics Lab IMA & IfU, RWTH Aachen University , Dennewartstraße 27, Aachen 52068, Germany
Frank Hellmann: Department of Complexity Science, Potsdam Institute for Climate Impact Research , Telegrafenberg A 31, Potsdam, Brandenburg 14473, Germany

DOI: https://doi.org/10.1088/1367-2630/ac54c9
Journal volume & issue: Vol. 24, no. 4
p. 043041

Abstract

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The prediction of dynamical stability of power grids becomes more important and challenging with increasing shares of renewable energy sources due to their decentralized structure, reduced inertia and volatility. We investigate the feasibility of applying graph neural networks (GNN) to predict dynamic stability of synchronisation in complex power grids using the single-node basin stability (SNBS) as a measure. To do so, we generate two synthetic datasets for grids with 20 and 100 nodes respectively and estimate SNBS using Monte-Carlo sampling. Those datasets are used to train and evaluate the performance of eight different GNN-models. All models use the full graph without simplifications as input and predict SNBS in a nodal-regression-setup. We show that SNBS can be predicted in general and the performance significantly changes using different GNN-models. Furthermore, we observe interesting transfer capabilities of our approach: GNN-models trained on smaller grids can directly be applied on larger grids without the need of retraining.

Published in New Journal of Physics

ISSN: 1367-2630 (Online)
Publisher: IOP Publishing
Country of publisher: United Kingdom
LCC subjects: Science: Physics
Website: https://iopscience.iop.org/journal/1367-2630

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