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Tight Regret Bounds for Bayesian Optimization in One Dimension

Machine Learning 2025-05-08 v3 Information Theory Machine Learning math.IT Optimization and Control

Abstract

We consider the problem of Bayesian optimization (BO) in one dimension, under a Gaussian process prior and Gaussian sampling noise. We provide a theoretical analysis showing that, under fairly mild technical assumptions on the kernel, the best possible cumulative regret up to time TT behaves as Ω(T)\Omega(\sqrt{T}) and O(TlogT)O(\sqrt{T\log T}). This gives a tight characterization up to a logT\sqrt{\log T} factor, and includes the first non-trivial lower bound for noisy BO. Our assumptions are satisfied, for example, by the squared exponential and Mat\'ern-ν\nu kernels, with the latter requiring ν>2\nu > 2. Our results certify the near-optimality of existing bounds (Srinivas {\em et al.}, 2009) for the SE kernel, while proving them to be strictly suboptimal for the Mat\'ern kernel with ν>2\nu > 2.

Keywords

Cite

@article{arxiv.1805.11792,
  title  = {Tight Regret Bounds for Bayesian Optimization in One Dimension},
  author = {Jonathan Scarlett},
  journal= {arXiv preprint arXiv:1805.11792},
  year   = {2025}
}

Comments

ICML 2018 + supplementary material. This version also includes an 'Errata' section correcting two minor mistakes

R2 v1 2026-06-23T02:12:51.208Z