Lower Bounds on Regret for Noisy Gaussian Process Bandit Optimization

Abstract

In this paper, we consider the problem of sequentially optimizing a black-box function f based on noisy samples and bandit feedback. We assume that f is smooth in the sense of having a bounded norm in some reproducing kernel Hilbert space (RKHS), yielding a commonly-considered non-Bayesian form of Gaussian process bandit optimization. We provide algorithm-independent lower bounds on the simple regret, measuring the suboptimality of a single point reported after T rounds, and on the cumulative regret, measuring the sum of regrets over the T chosen points. For the isotropic squared-exponential kernel in d dimensions, we find that an average simple regret of ε requires T = (1ε2 (1ε)d/2), and the average cumulative regret is at least ( T( T)d/2 ), thus matching existing upper bounds up to the replacement of d/2 by 2d+O(1) in both cases. For the Mat\'ern- kernel, we give analogous bounds of the form ( (1ε)2+d/) and ( T + d2 + d ), and discuss the resulting gaps to the existing upper bounds.