Gibbon: General-purpose information-based bayesian optimisation
Journal of Machine Learning Research, 2021•jmlr.org
This paper describes a general-purpose extension of max-value entropy search, a popular
approach for Bayesian Optimisation (BO). A novel approximation is proposed for the
information gain--an information-theoretic quantity central to solving a range of BO
problems, including noisy, multi-fidelity and batch optimisations across both continuous and
highly-structured discrete spaces. Previously, these problems have been tackled separately
within information-theoretic BO, each requiring a different sophisticated approximation …
approach for Bayesian Optimisation (BO). A novel approximation is proposed for the
information gain--an information-theoretic quantity central to solving a range of BO
problems, including noisy, multi-fidelity and batch optimisations across both continuous and
highly-structured discrete spaces. Previously, these problems have been tackled separately
within information-theoretic BO, each requiring a different sophisticated approximation …
This paper describes a general-purpose extension of max-value entropy search, a popular approach for Bayesian Optimisation (BO). A novel approximation is proposed for the information gain -- an information-theoretic quantity central to solving a range of BO problems, including noisy, multi-fidelity and batch optimisations across both continuous and highly-structured discrete spaces. Previously, these problems have been tackled separately within information-theoretic BO, each requiring a different sophisticated approximation scheme, except for batch BO, for which no computationally-lightweight information-theoretic approach has previously been proposed. GIBBON (General-purpose Information-Based Bayesian OptimisatioN) provides a single principled framework suitable for all the above, out-performing existing approaches whilst incurring substantially lower computational overheads. In addition, GIBBON does not require the problem's search space to be Euclidean and so is the first high-performance yet computationally light-weight acquisition function that supports batch BO over general highly structured input spaces like molecular search and gene design. Moreover, our principled derivation of GIBBON yields a natural interpretation of a popular batch BO heuristic based on determinantal point processes. Finally, we analyse GIBBON across a suite of synthetic benchmark tasks, a molecular search loop, and as part of a challenging batch multi-fidelity framework for problems with controllable experimental noise.
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