Quantum machine learning models for graphs
Abstract
Geometric Machine Learning (GML) successes have been achieved through the thorough study and design of new equivariant neural networks. In comparison, geometric quantum machine learning (GQML) models lack such a detailed understanding and, despite already several proposals, a unifying perspective on their design remains elusive. In this work, we focus on GQML models for graph problems that showcase a lot of structure and still remain frontier in machine learning. For the case when n-node graphs are encoded in n-qubit states, we provide a comprehensive characterization of their constituents. Taken together, these furnish us with a toolbox for the design of quantum graph models, and we further probe its benefits including the natural integration with classical models, generalization of known GQML models (sometimes extending their expressivity at virtually no cost), and straightforward classical pre-training strategies. The latter two features are demonstrated in dedicated numerical experiments.
Cite
@article{arxiv.2607.00698,
title = {Quantum machine learning models for graphs},
author = {Frédéric Sauvage and Pranav Kalidindi and Frederic Rapp and Martın Larocca},
journal= {arXiv preprint arXiv:2607.00698},
year = {2026}
}