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Main Authors: Motoyama, Yuichi, Yoshimi, Kazuyoshi, Aoyama, Tatsumi, Terayama, Kei, Tsuda, Koji, Tamura, Ryo
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.01349
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author Motoyama, Yuichi
Yoshimi, Kazuyoshi
Aoyama, Tatsumi
Terayama, Kei
Tsuda, Koji
Tamura, Ryo
author_facet Motoyama, Yuichi
Yoshimi, Kazuyoshi
Aoyama, Tatsumi
Terayama, Kei
Tsuda, Koji
Tamura, Ryo
contents Bayesian optimization (BO) is widely used to accelerate physics and materials research, where objective function evaluations are computationally or experimentally expensive. While many BO frameworks focus on algorithmic efficiency, practical usability and portability are equally critical for sustained use in real research environments. PHYSBO is a Bayesian optimization library designed to address these needs by enabling optimization over user-defined candidate pools and by supporting domain-specific problem settings. This paper presents the major updates introduced in PHYSBO versions 2 and 3, with a focus on improvements in usability, portability, and practical deployment rather than on new optimization algorithms. In PHYSBO version 2, the software license was changed from GPL to MPL to improve compatibility with a wider range of research and software ecosystems. Building on this revision, PHYSBO version 3 introduces a set of implementation-oriented updates aimed at improving usability and portability, without modifying the core optimization algorithms. These updates include improvements in computational performance and scalability, extended support for multi-objective optimization, the introduction of range-based policies for continuous-variable optimization, the removal of environment-dependent components such as tightly coupled Cython modules, and compatibility with NumPy 2. These improvements reduce the technical and organizational burden on users, enabling PHYSBO to be deployed across diverse computing environments and research workflows. By emphasizing portability and ease of integration while maintaining sufficient performance, PHYSBO version 3 is positioned as a sustainable research infrastructure for Bayesian optimization in physics and materials science.
format Preprint
id arxiv_https___arxiv_org_abs_2603_01349
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Update of PHYSBO: Improving Usability and Portability of Bayesian Optimization for Physics and Materials Research
Motoyama, Yuichi
Yoshimi, Kazuyoshi
Aoyama, Tatsumi
Terayama, Kei
Tsuda, Koji
Tamura, Ryo
Computational Physics
Materials Science
Bayesian optimization (BO) is widely used to accelerate physics and materials research, where objective function evaluations are computationally or experimentally expensive. While many BO frameworks focus on algorithmic efficiency, practical usability and portability are equally critical for sustained use in real research environments. PHYSBO is a Bayesian optimization library designed to address these needs by enabling optimization over user-defined candidate pools and by supporting domain-specific problem settings. This paper presents the major updates introduced in PHYSBO versions 2 and 3, with a focus on improvements in usability, portability, and practical deployment rather than on new optimization algorithms. In PHYSBO version 2, the software license was changed from GPL to MPL to improve compatibility with a wider range of research and software ecosystems. Building on this revision, PHYSBO version 3 introduces a set of implementation-oriented updates aimed at improving usability and portability, without modifying the core optimization algorithms. These updates include improvements in computational performance and scalability, extended support for multi-objective optimization, the introduction of range-based policies for continuous-variable optimization, the removal of environment-dependent components such as tightly coupled Cython modules, and compatibility with NumPy 2. These improvements reduce the technical and organizational burden on users, enabling PHYSBO to be deployed across diverse computing environments and research workflows. By emphasizing portability and ease of integration while maintaining sufficient performance, PHYSBO version 3 is positioned as a sustainable research infrastructure for Bayesian optimization in physics and materials science.
title Update of PHYSBO: Improving Usability and Portability of Bayesian Optimization for Physics and Materials Research
topic Computational Physics
Materials Science
url https://arxiv.org/abs/2603.01349