Binarizing Physics-Inspired GNNs for Combinatorial Optimization
Abstract
Physics-inspired graph neural networks (PI-GNNs) have been utilized as an efficient unsupervised framework for relaxing combinatorial optimization problems encoded through a specific graph structure and loss, reflecting dependencies between the problem's variables. While the framework has yielded promising results in various combinatorial problems, we show that the performance of PI-GNNs systematically plummets with an increasing density of the combinatorial problem graphs. Our analysis reveals an interesting phase transition in the PI-GNNs' training dynamics, associated with degenerate solutions for the denser problems, highlighting a discrepancy between the relaxed, real-valued model outputs and the binary-valued problem solutions. To address the discrepancy, we propose principled alternatives to the naive strategy used in PI-GNNs by building on insights from fuzzy logic and binarized neural networks. Our experiments demonstrate that the portfolio of proposed methods significantly improves the performance of PI-GNNs in increasingly dense settings.
Cite
@article{arxiv.2507.13703,
title = {Binarizing Physics-Inspired GNNs for Combinatorial Optimization},
author = {Martin Krutský and Gustav Šír and Vyacheslav Kungurtsev and Georgios Korpas},
journal= {arXiv preprint arXiv:2507.13703},
year = {2025}
}
Comments
Accepted to the 28th European Conference on Artificial Intelligence (ECAI 2025). This archival version includes supplementary appendices