English

Gaussian Process Planning with Lipschitz Continuous Reward Functions: Towards Unifying Bayesian Optimization, Active Learning, and Beyond

Machine Learning 2015-11-24 v1 Artificial Intelligence Machine Learning Robotics

Abstract

This paper presents a novel nonmyopic adaptive Gaussian process planning (GPP) framework endowed with a general class of Lipschitz continuous reward functions that can unify some active learning/sensing and Bayesian optimization criteria and offer practitioners some flexibility to specify their desired choices for defining new tasks/problems. In particular, it utilizes a principled Bayesian sequential decision problem framework for jointly and naturally optimizing the exploration-exploitation trade-off. In general, the resulting induced GPP policy cannot be derived exactly due to an uncountable set of candidate observations. A key contribution of our work here thus lies in exploiting the Lipschitz continuity of the reward functions to solve for a nonmyopic adaptive epsilon-optimal GPP (epsilon-GPP) policy. To plan in real time, we further propose an asymptotically optimal, branch-and-bound anytime variant of epsilon-GPP with performance guarantee. We empirically demonstrate the effectiveness of our epsilon-GPP policy and its anytime variant in Bayesian optimization and an energy harvesting task.

Keywords

Cite

@article{arxiv.1511.06890,
  title  = {Gaussian Process Planning with Lipschitz Continuous Reward Functions: Towards Unifying Bayesian Optimization, Active Learning, and Beyond},
  author = {Chun Kai Ling and Kian Hsiang Low and Patrick Jaillet},
  journal= {arXiv preprint arXiv:1511.06890},
  year   = {2015}
}

Comments

30th AAAI Conference on Artificial Intelligence (AAAI 2016), Extended version with proofs, 17 pages

R2 v1 2026-06-22T11:51:12.551Z