On Information Gain and Regret Bounds in Gaussian Process Bandits

Abstract

Consider the sequential optimization of an expensive to evaluate and possibly non-convex objective function f from noisy feedback, that can be considered as a continuum-armed bandit problem. Upper bounds on the regret performance of several learning algorithms (GP-UCB, GP-TS, and their variants) are known under both a Bayesian (when f is a sample from a Gaussian process (GP)) and a frequentist (when f lives in a reproducing kernel Hilbert space) setting. The regret bounds often rely on the maximal information gain γT between T observations and the underlying GP (surrogate) model. We provide general bounds on γT based on the decay rate of the eigenvalues of the GP kernel, whose specialisation for commonly used kernels, improves the existing bounds on γT, and subsequently the regret bounds relying on γT under numerous settings. For the Mat\'ern family of kernels, where the lower bounds on γT, and regret under the frequentist setting, are known, our results close a huge polynomial in T gap between the upper and lower bounds (up to logarithmic in T factors).