AQKA: Active Quantum Kernel Acquisition Under a Shot Budget
Abstract
Estimating an quantum kernel from circuit fidelities requires measurement shots, the dominant bottleneck for deployment on near-term hardware. Existing budget-saving methods (Nystr\"om-QKE, ShoFaR, kernel-target alignment) sub-sample \emph{which} entries to measure but allocate shots \emph{uniformly} within their chosen subset, ignoring how much each entry drives the downstream classifier. We close this gap with two contributions. \textbf{First, a complete regime decomposition} for shot-budgeted quantum kernel learning: a principled menu of when each allocator wins. Our method, \emph{AQKA}, dominates the budget-limited regime () on sparse-sensitivity KRR, with the gap \emph{growing} from to pts over uniform as scales and reaching -- pts on an \texttt{ibm\_pittsburgh} (156-qubit Heron) hardware kernel; Nystr\"om-QKE wins at saturating budgets on planted-sparse via low-rank reconstruction; ShoFaR is competitive only at extreme low budgets. \textbf{Second, a closed-form pair-level acquisition theory}: with explicit gradient for KRR (Lemma~1, ) and SVM via the envelope theorem (); a \emph{corrected} sparsity-aware Cauchy--Schwarz rate matching empirics (vs.\ the naive ); an explicit-constant plug-in regret bound (Theorem~2); and a tighter SVM ceiling . We close with the first multi-seed live online adaptive shot allocation on quantum hardware: pts at on \texttt{ibm\_aachen} (, 5 seeds), with the advantage holding at at higher budget on \texttt{ibm\_berlin} ( pts, 5 seeds).
Cite
@article{arxiv.2605.14672,
title = {AQKA: Active Quantum Kernel Acquisition Under a Shot Budget},
author = {Jian Xu and Chao Li and Delu Zeng and John Paisley and Qibin Zhao},
journal= {arXiv preprint arXiv:2605.14672},
year = {2026}
}