Regret Bounds for Meta Bayesian Optimization with an Unknown Gaussian Process Prior

Zi Wang, Beomjoon Kim, Leslie Pack Kaelbling

NeurIPS 2018 pp. 10477-10488

/neurips/2018/wang2018neurips-regret/

Abstract

Bayesian optimization usually assumes that a Bayesian prior is given. However, the strong theoretical guarantees in Bayesian optimization are often regrettably compromised in practice because of unknown parameters in the prior. In this paper, we adopt a variant of empirical Bayes and show that, by estimating the Gaussian process prior from offline data sampled from the same prior and constructing unbiased estimators of the posterior, variants of both GP-UCB and \emph{probability of improvement} achieve a near-zero regret bound, which decreases to a constant proportional to the observational noise as the number of offline data and the number of online evaluations increase. Empirically, we have verified our approach on challenging simulated robotic problems featuring task and motion planning.

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Cite

Text

Wang et al. "Regret Bounds for Meta Bayesian Optimization with an Unknown Gaussian Process Prior." Neural Information Processing Systems, 2018.

Markdown

[Wang et al. "Regret Bounds for Meta Bayesian Optimization with an Unknown Gaussian Process Prior." Neural Information Processing Systems, 2018.](https://mlanthology.org/neurips/2018/wang2018neurips-regret/)

BibTeX

@inproceedings{wang2018neurips-regret,
  title     = {{Regret Bounds for Meta Bayesian Optimization with an Unknown Gaussian Process Prior}},
  author    = {Wang, Zi and Kim, Beomjoon and Kaelbling, Leslie Pack},
  booktitle = {Neural Information Processing Systems},
  year      = {2018},
  pages     = {10477-10488},
  url       = {https://mlanthology.org/neurips/2018/wang2018neurips-regret/}
}