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Main Authors: Berezin, Aleksandr, Balduin, Stephan, Oberließen, Thomas, Peter, Sebastian, Veith, Eric MSP
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2408.05787
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author Berezin, Aleksandr
Balduin, Stephan
Oberließen, Thomas
Peter, Sebastian
Veith, Eric MSP
author_facet Berezin, Aleksandr
Balduin, Stephan
Oberließen, Thomas
Peter, Sebastian
Veith, Eric MSP
contents This paper addresses the challenge of neural state estimation in power distribution systems. We identified a research gap in the current state of the art, which lies in the inability of models to adapt to changes in the power grid, such as loss of sensors and branch switching, in a zero-shot fashion. Based on the literature, we identified graph neural networks as the most promising class of models for this use case. Our experiments confirm their robustness to some grid changes and also show that a deeper network does not always perform better. We propose data augmentations to improve performance and conduct a comprehensive grid search of different model configurations for common zero-shot learning scenarios.
format Preprint
id arxiv_https___arxiv_org_abs_2408_05787
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle On zero-shot learning in neural state estimation of power distribution systems
Berezin, Aleksandr
Balduin, Stephan
Oberließen, Thomas
Peter, Sebastian
Veith, Eric MSP
Machine Learning
Systems and Control
This paper addresses the challenge of neural state estimation in power distribution systems. We identified a research gap in the current state of the art, which lies in the inability of models to adapt to changes in the power grid, such as loss of sensors and branch switching, in a zero-shot fashion. Based on the literature, we identified graph neural networks as the most promising class of models for this use case. Our experiments confirm their robustness to some grid changes and also show that a deeper network does not always perform better. We propose data augmentations to improve performance and conduct a comprehensive grid search of different model configurations for common zero-shot learning scenarios.
title On zero-shot learning in neural state estimation of power distribution systems
topic Machine Learning
Systems and Control
url https://arxiv.org/abs/2408.05787