Sequential Test for the Lowest Mean: From Thompson to Murphy Sampling
Abstract
Learning the minimum/maximum mean among a finite set of distributions is a fundamental sub-task in planning, game tree search and reinforcement learning. We formalize this learning task as the problem of sequentially testing how the minimum mean among a finite set of distributions compares to a given threshold. We develop refined non-asymptotic lower bounds, which show that optimality mandates very different sampling behavior for a low vs high true minimum. We show that Thompson Sampling and the intuitive Lower Confidence Bounds policy each nail only one of these cases. We develop a novel approach that we call Murphy Sampling. Even though it entertains exclusively low true minima, we prove that MS is optimal for both possibilities. We then design advanced self-normalized deviation inequalities, fueling more aggressive stopping rules. We complement our theoretical guarantees by experiments showing that MS works best in practice.
Cite
@article{arxiv.1806.00973,
title = {Sequential Test for the Lowest Mean: From Thompson to Murphy Sampling},
author = {Emilie Kaufmann and Wouter Koolen and Aurelien Garivier},
journal= {arXiv preprint arXiv:1806.00973},
year = {2018}
}