Quantum Speedups of Optimizing Approximately Convex Functions with Applications to Logarithmic Regret Stochastic Convex Bandits

Abstract

We initiate the study of quantum algorithms for optimizing approximately convex functions. Given a convex set K⊂eqRn and a function Fn such that there exists a convex function f satisfying x∈ K|F(x)-f(x)|≤ ε/n, our quantum algorithm finds an x*∈ K such that F(x*)-x∈ K F(x)≤ε using O(n3) quantum evaluation queries to F. This achieves a polynomial quantum speedup compared to the best-known classical algorithms. As an application, we give a quantum algorithm for zeroth-order stochastic convex bandits with O(n52 T) regret, an exponential speedup in T compared to the classical (T) lower bound. Technically, we achieve quantum speedup in n by exploiting a quantum framework of simulated annealing and adopting a quantum version of the hit-and-run walk. Our speedup in T for zeroth-order stochastic convex bandits is due to a quadratic quantum speedup in multiplicative error of mean estimation.