English

Finite-Time Logarithmic Bayes Regret Upper Bounds

Machine Learning 2024-01-23 v3 Machine Learning

Abstract

We derive the first finite-time logarithmic Bayes regret upper bounds for Bayesian bandits. In a multi-armed bandit, we obtain O(cΔlogn)O(c_\Delta \log n) and O(chlog2n)O(c_h \log^2 n) upper bounds for an upper confidence bound algorithm, where chc_h and cΔc_\Delta are constants depending on the prior distribution and the gaps of bandit instances sampled from it, respectively. The latter bound asymptotically matches the lower bound of Lai (1987). Our proofs are a major technical departure from prior works, while being simple and general. To show the generality of our techniques, we apply them to linear bandits. Our results provide insights on the value of prior in the Bayesian setting, both in the objective and as a side information given to the learner. They significantly improve upon existing O~(n)\tilde{O}(\sqrt{n}) bounds, which have become standard in the literature despite the logarithmic lower bound of Lai (1987).

Keywords

Cite

@article{arxiv.2306.09136,
  title  = {Finite-Time Logarithmic Bayes Regret Upper Bounds},
  author = {Alexia Atsidakou and Branislav Kveton and Sumeet Katariya and Constantine Caramanis and Sujay Sanghavi},
  journal= {arXiv preprint arXiv:2306.09136},
  year   = {2024}
}
R2 v1 2026-06-28T11:05:58.524Z