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Maximizing acquisition functions for Bayesian optimization

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arxiv 1805.10196 v2 pith:SOPM5BTI submitted 2018-05-25 stat.ML cs.LG

Maximizing acquisition functions for Bayesian optimization

classification stat.ML cs.LG
keywords functionsacquisitionoptimizationbayesianmaximizingachieveamenableapproach
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Bayesian optimization is a sample-efficient approach to global optimization that relies on theoretically motivated value heuristics (acquisition functions) to guide its search process. Fully maximizing acquisition functions produces the Bayes' decision rule, but this ideal is difficult to achieve since these functions are frequently non-trivial to optimize. This statement is especially true when evaluating queries in parallel, where acquisition functions are routinely non-convex, high-dimensional, and intractable. We first show that acquisition functions estimated via Monte Carlo integration are consistently amenable to gradient-based optimization. Subsequently, we identify a common family of acquisition functions, including EI and UCB, whose properties not only facilitate but justify use of greedy approaches for their maximization.

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