Near-Optimal Algorithm for Non-Stationary Kernelized Bandits
Abstract
This paper studies a non-stationary kernelized bandit (KB) problem, also called time-varying Bayesian optimization, where one seeks to minimize the regret under an unknown reward function that varies over time. In particular, we focus on a near-optimal algorithm whose regret upper bound matches the regret lower bound. For this goal, we show the first algorithm-independent regret lower bound for non-stationary KB with squared exponential and Mat\'ern kernels, which reveals that an existing optimization-based KB algorithm with slight modification is near-optimal. However, this existing algorithm suffers from feasibility issues due to its huge computational cost. Therefore, we propose a novel near-optimal algorithm called restarting phased elimination with random permutation (R-PERP), which bypasses the huge computational cost. A technical key point is the simple permutation procedures of query candidates, which enable us to derive a novel tighter confidence bound tailored to the non-stationary problems.
Cite
@article{arxiv.2410.16052,
title = {Near-Optimal Algorithm for Non-Stationary Kernelized Bandits},
author = {Shogo Iwazaki and Shion Takeno},
journal= {arXiv preprint arXiv:2410.16052},
year = {2024}
}
Comments
24 pages, 2 figures