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Main Authors: Meng, Dekang, Haider, Rabab, van Hentenryck, Pascal
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.01951
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author Meng, Dekang
Haider, Rabab
van Hentenryck, Pascal
author_facet Meng, Dekang
Haider, Rabab
van Hentenryck, Pascal
contents This paper introduces OptiGridML, a machine learning framework for discrete topology optimization in power grids. The task involves selecting substation breaker configurations that maximize cross-region power exports, a problem typically formulated as a mixed-integer program (MIP) that is NP-hard and computationally intractable for large networks. OptiGridML replaces repeated MIP solves with a two-stage neural architecture: a line-graph neural network (LGNN) that approximates DC power flows for a given network topology, and a heterogeneous GNN (HeteroGNN) that predicts breaker states under structural and physical constraints. A physics-informed consistency loss connects these components by enforcing Kirchhoff's law on predicted flows. Experiments on synthetic networks with up to 1,000 breakers show that OptiGridML achieves power export improvements of up to 18% over baseline topologies, while reducing inference time from hours to milliseconds. These results demonstrate the potential of structured, flow-aware GNNs for accelerating combinatorial optimization in physical networked systems.
format Preprint
id arxiv_https___arxiv_org_abs_2508_01951
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Flow-Aware GNN for Transmission Network Reconfiguration via Substation Breaker Optimization
Meng, Dekang
Haider, Rabab
van Hentenryck, Pascal
Machine Learning
Artificial Intelligence
This paper introduces OptiGridML, a machine learning framework for discrete topology optimization in power grids. The task involves selecting substation breaker configurations that maximize cross-region power exports, a problem typically formulated as a mixed-integer program (MIP) that is NP-hard and computationally intractable for large networks. OptiGridML replaces repeated MIP solves with a two-stage neural architecture: a line-graph neural network (LGNN) that approximates DC power flows for a given network topology, and a heterogeneous GNN (HeteroGNN) that predicts breaker states under structural and physical constraints. A physics-informed consistency loss connects these components by enforcing Kirchhoff's law on predicted flows. Experiments on synthetic networks with up to 1,000 breakers show that OptiGridML achieves power export improvements of up to 18% over baseline topologies, while reducing inference time from hours to milliseconds. These results demonstrate the potential of structured, flow-aware GNNs for accelerating combinatorial optimization in physical networked systems.
title Flow-Aware GNN for Transmission Network Reconfiguration via Substation Breaker Optimization
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2508.01951