Beyond Optimization: Harnessing Quantum Annealer Dynamics for Machine Learning
Quantum Physics
2026-02-10 v3
Abstract
Quantum annealing is typically regarded as a tool for combinatorial optimization, but its coherent dynamics also offer potential for machine learning. We present a model that encodes classical data into an Ising Hamiltonian, evolves it on a quantum annealer, and uses the resulting probability distributions as feature maps for classification. Experiments on the quantum annealer machine with the Digits dataset, together with simulations on MNIST, demonstrate that short annealing times yield higher classification accuracy, while longer times reduce accuracy but lower sampling costs. We introduce the participation ratio as a measure of the effective model size and show its strong correlation with generalization.
Cite
@article{arxiv.2601.09938,
title = {Beyond Optimization: Harnessing Quantum Annealer Dynamics for Machine Learning},
author = {Akitada Sakurai and Aoi Hayashi and Tadayoshi Matsumori and Daisuke Kaji and Tadashi Kadowaki and Kae Nemoto},
journal= {arXiv preprint arXiv:2601.09938},
year = {2026}
}
Comments
6pages, 3 figures