AQKA: Active Quantum Kernel Acquisition Under a Shot Budget

Abstract

Estimating an N × N quantum kernel from circuit fidelities requires Θ(N2 S) measurement shots, the dominant bottleneck for deployment on near-term hardware. Existing budget-saving methods (Nyström-QKE, ShoFaR, kernel-target alignment) sub-sample which entries to measure but allocate shots uniformly within their chosen subset, ignoring how much each entry drives the downstream classifier. We close this gap with two contributions. First, a complete regime decomposition for shot-budgeted quantum kernel learning: a principled menu of when each allocator wins. Our method, AQKA, dominates the budget-limited regime (B 16 npairs) on sparse-sensitivity KRR, with the gap growing from +8 to +25 pts over uniform as N scales 2251000 and reaching +26--32 pts on an ibm\pittsburgh (156-qubit Heron) hardware kernel; Nyström-QKE wins at saturating budgets on planted-sparse via low-rank reconstruction; ShoFaR is competitive only at extreme low budgets. Second, a closed-form pair-level acquisition theory: sij |gij|Kij(1-Kij) with explicit gradient gij for KRR (Lemma~1, |βiαj+βjαi|Kij(1-Kij)) and SVM via the envelope theorem (|ηi*ηj*|Kij(1-Kij)); a corrected sparsity-aware Cauchy--Schwarz rate ρ 2m/N matching empirics (vs.\ the naive m2/N2); an explicit-constant plug-in regret bound (Theorem~2); and a tighter SVM ceiling ρSVM msv2/N2. We close with the first multi-seed live online adaptive shot allocation on quantum hardware: +17.0 4.8 pts at N=20 on ibm\aachen (3.5σ, 5 seeds), with the advantage holding at N=30 at higher budget on ibm\berlin (+14.0 8.5 pts, 5 seeds).