Training-Free Certified Bounds for Quantum Regression: A Scalable Framework
Abstract
We present a training-free, certified error bound for quantum regression derived directly from Pauli expectation values. Generalizing the heuristic of minimum accuracy from classification to regression, we evaluate axis-aligned predictors within the Pauli feature space. We formally prove that the optimal axis-aligned predictor constitutes a rigorous upper bound on the minimum training Mean Squared Error (MSE) attainable by any linear or kernel-based regressor defined on the same quantum feature map. Since computing this exact bound requires an intractable scan of the full Pauli basis, we introduce a Monte Carlo framework to efficiently estimate it using a tractable subset of measurement axes. We further provide non-asymptotic statistical guarantees to certify performance within a practical measurement budget. This method enables rapid comparison of quantum feature maps and early diagnosis of expressivity, allowing for the informed selection of architectures before deploying higher-complexity models.
Cite
@article{arxiv.2601.00745,
title = {Training-Free Certified Bounds for Quantum Regression: A Scalable Framework},
author = {Demerson N. Gonçalves and Tharso D. Fernandes and Pedro H. G. Lugao and João T. Dias},
journal= {arXiv preprint arXiv:2601.00745},
year = {2026}
}
Comments
16 pages, 3 tables