Global Optimization of Gaussian Process Acquisition Functions Using a Piecewise-Linear Kernel Approximation
Abstract
Bayesian optimization relies on iteratively constructing and optimizing an acquisition function. The latter turns out to be a challenging, non-convex optimization problem itself. Despite the relative importance of this step, most algorithms employ sampling- or gradient-based methods, which do not provably converge to global optima. This work investigates mixed-integer programming (MIP) as a paradigm for global acquisition function optimization. Specifically, our Piecewise-linear Kernel Mixed Integer Quadratic Programming (PK-MIQP) formulation introduces a piecewise-linear approximation for Gaussian process kernels and admits a corresponding MIQP representation for acquisition functions. The proposed method is applicable to uncertainty-based acquisition functions for any stationary or dot-product kernel. We analyze the theoretical regret bounds of the proposed approximation, and empirically demonstrate the framework on synthetic functions, constrained benchmarks, and a hyperparameter tuning task.
Cite
@article{arxiv.2410.16893,
title = {Global Optimization of Gaussian Process Acquisition Functions Using a Piecewise-Linear Kernel Approximation},
author = {Yilin Xie and Shiqiang Zhang and Joel A. Paulson and Calvin Tsay},
journal= {arXiv preprint arXiv:2410.16893},
year = {2026}
}
Comments
17 pages, 4 figures, 5 tables