Robustness of Quantum Algorithms for Nonconvex Optimization
Abstract
Recent results suggest that quantum computers possess the potential to speed up nonconvex optimization problems. However, a crucial factor for the implementation of quantum optimization algorithms is their robustness against experimental and statistical noises. In this paper, we systematically study quantum algorithms for finding an -approximate second-order stationary point (-SOSP) of a -dimensional nonconvex function, a fundamental problem in nonconvex optimization, with noisy zeroth- or first-order oracles as inputs. We first prove that, up to noise of , accelerated perturbed gradient descent with quantum gradient estimation takes quantum queries to find an -SOSP. We then prove that perturbed gradient descent is robust to the noise of and for on the zeroth- and first-order oracles, respectively, which provides a quantum algorithm with poly-logarithmic query complexity. We then propose a stochastic gradient descent algorithm using quantum mean estimation on the Gaussian smoothing of noisy oracles, which is robust to and noise on the zeroth- and first-order oracles, respectively. The quantum algorithm takes and queries to the two oracles, giving a polynomial speedup over the classical counterparts. Moreover, we characterize the domains where quantum algorithms can find an -SOSP with poly-logarithmic, polynomial, or exponential number of queries in , or the problem is information-theoretically unsolvable even by an infinite number of queries. In addition, we prove an lower bound in for any randomized classical and quantum algorithm to find an -SOSP using either noisy zeroth- or first-order oracles.
Cite
@article{arxiv.2212.02548,
title = {Robustness of Quantum Algorithms for Nonconvex Optimization},
author = {Weiyuan Gong and Chenyi Zhang and Tongyang Li},
journal= {arXiv preprint arXiv:2212.02548},
year = {2022}
}