A Fundamental Bound for Robust Quantum Gate Control
Abstract
We derive a universal performance limit for coherent quantum control in the presence of modeled and unmodeled uncertainties. For any target unitary that is implementable in the absence of error, we prove that the worst-case (and hence the average) gate fidelity obeys the lower bound , where is the gate duration and is a single frequency-like measure that aggregates \emph{all} bounded uncertainty sources, e.g., coherent control imperfections, unknown couplings, and residual environment interactions, without assuming an initially factorizable system-bath state or a completely positive map. The bound is obtained by combining an interaction-picture averaging method with a Bellman-Gronwall inequality and holds for any finite-norm Hamiltonian decomposition. Hence it applies equally to qubits, multi-level qudits, and ancilla-assisted operations. Because depends only on the dimensionless product , it yields a device-independent metric that certifies whether a given hardware platform can, in principle, reach a specified fault-tolerance threshold, and also sets a quantitative target for robust-control synthesis and system identification.
Cite
@article{arxiv.2507.01215,
title = {A Fundamental Bound for Robust Quantum Gate Control},
author = {Robert L. Kosut and Daniel A. Lidar and Herschel Rabitz},
journal= {arXiv preprint arXiv:2507.01215},
year = {2025}
}