Self-Adjusting Weighted Expected Improvement for Bayesian Optimization

verfasst von: Carolin Benjamins, Elena Raponi, Anja Jankovic, Carola Doerr, Marius Lindauer
Abstract: Bayesian Optimization (BO) is a class of surrogate-based, sample-efficient algorithms for optimizing black-box problems with small evaluation budgets.
The BO pipeline itself is highly configurable with many different design choices regarding the initial design, surrogate model, and acquisition function (AF).
Unfortunately, our understanding of how to select suitable components for a problem at hand is very limited.
In this work, we focus on the definition of the AF, whose main purpose is to balance the trade-off between exploring regions with high uncertainty and those with high promise for good solutions.
We propose Self-Adjusting Weighted Expected Improvement (SAWEI), where we let the exploration-exploitation trade-off self-adjust in a data-driven manner, based on a convergence criterion for BO.
On the noise-free black-box BBOB functions of the COCO benchmarking platform, our method exhibits a favorable any-time performance compared to handcrafted baselines and serves as a robust default choice for any problem structure.
The suitability of our method also transfers to HPOBench.
With SAWEI, we are a step closer to on-the-fly, data-driven, and robust BO designs that automatically adjust their sampling behavior to the problem at hand.
Organisationseinheit(en): Institut für Informationsverarbeitung
Fachgebiet Maschinelles Lernen
Institut für Künstliche Intelligenz
Externe Organisation(en): Technische Universität München (TUM)
Computer Lab of Paris 6 (Lip6)
Centre national de la recherche scientifique (CNRS)
Sorbonne Université
Typ: Aufsatz in Konferenzband
Publikationsdatum: 2023
Publikationsstatus: Angenommen/Im Druck
Peer-reviewed: Ja

BibTeX

@inproceedings{7074dc2996724ffaa54e41537c4d2687,
title = "Self-Adjusting Weighted Expected Improvement for Bayesian Optimization",
abstract = "Bayesian Optimization (BO) is a class of surrogate-based, sample-efficient algorithms for optimizing black-box problems with small evaluation budgets.The BO pipeline itself is highly configurable with many different design choices regarding the initial design, surrogate model, and acquisition function (AF).Unfortunately, our understanding of how to select suitable components for a problem at hand is very limited.In this work, we focus on the definition of the AF, whose main purpose is to balance the trade-off between exploring regions with high uncertainty and those with high promise for good solutions.We propose Self-Adjusting Weighted Expected Improvement (SAWEI), where we let the exploration-exploitation trade-off self-adjust in a data-driven manner, based on a convergence criterion for BO.On the noise-free black-box BBOB functions of the COCO benchmarking platform, our method exhibits a favorable any-time performance compared to handcrafted baselines and serves as a robust default choice for any problem structure.The suitability of our method also transfers to HPOBench.With SAWEI, we are a step closer to on-the-fly, data-driven, and robust BO designs that automatically adjust their sampling behavior to the problem at hand. ",
keywords = "Bayesian Optimization, Acquisition Function, Dynamic Algorithm Configuration, Weighted Expected Improvement, Upper Bound Regret",
author = "Carolin Benjamins and Elena Raponi and Anja Jankovic and Carola Doerr and Marius Lindauer",
year = "2023",
language = "English",
booktitle = "AutoML Conference 2023",
publisher = "PMLR",
}

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Self-Adjusting Weighted Expected Improvement for Bayesian Optimization

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