Local tensor-train surrogates for quantum learning models
Abstract
A key bottleneck in quantum machine learning is the computational cost of repeated quantum circuit evaluations during the inference phase. To address this, we present a framework for constructing fast, cheap, provably accurate classical tensor-train surrogates of fully trained quantum machine learning models within local patches of their input data space. The approach combines Taylor polynomial approximation with a tensor-train (TT) representation and embeds it in a statistical learning paradigm via empirical risk minimization. In our analysis, the Taylor-TT construction serves as a deterministic error certificate proving that the TT hypothesis class contains a good approximation; empirical risk minimization then provably recovers a surrogate with controlled generalization error and explicit bounds. This translates into three independently controllable error sources: (i) Taylor truncation error controlled by the patch radius and polynomial degree , (ii) TT approximation error controlled by the bond dimension , and (iii) statistical estimation error. While the parameter count scales polynomially in the number of data dimensions , i.e., rather than the naive , the worst-case constants inherit an exponential factor through the tensor-product feature norm during Taylor polynomial embedding onto TT. This cleanly separates representation complexity from feature-induced constants. Our risk bounds and sample complexity depend explicitly on the local patch radius .
Cite
@article{arxiv.2604.25631,
title = {Local tensor-train surrogates for quantum learning models},
author = {Sreeraj Rajindran Nair and Christopher Ferrie},
journal= {arXiv preprint arXiv:2604.25631},
year = {2026}
}
Comments
26 pages