Bayesian Optimization Algorithms for Accelerator Physics

Accelerator physics relies on numerical algorithms to solve optimization problems in online accelerator control and tasks such as experimental design and model calibration in simulations. The effectiveness of optimization algorithms in discovering ideal solutions for complex challenges with limited...

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Published inarXiv.org
Main Authors Roussel, Ryan, Edelen, Auralee L, Boltz, Tobias, Kennedy, Dylan, Zhang, Zhe, Ji, Fuhao, Huang, Xiaobiao, Ratner, Daniel, Andrea Santamaria Garcia, Xu, Chenran, Kaiser, Jan, Angel Ferran Pousa, Eichler, Annika, Lubsen, Jannis O, Isenberg, Natalie M, Gao, Yuan, Kuklev, Nikita, Martinez, Jose, Mustapha, Brahim, Kain, Verena, Lin, Weijian, Liuzzo, Simone Maria, Jason St John, Streeter, Matthew J V, Lehe, Remi, Neiswanger, Willie
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 05.04.2024
Subjects
Algorithms
Bayesian analysis
Complexity
Design of experiments
Optimization
Optimization algorithms
Optimization techniques
Physics
Physics - Accelerator Physics
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Summary:Accelerator physics relies on numerical algorithms to solve optimization problems in online accelerator control and tasks such as experimental design and model calibration in simulations. The effectiveness of optimization algorithms in discovering ideal solutions for complex challenges with limited resources often determines the problem complexity these methods can address. The accelerator physics community has recognized the advantages of Bayesian optimization algorithms, which leverage statistical surrogate models of objective functions to effectively address complex optimization challenges, especially in the presence of noise during accelerator operation and in resource-intensive physics simulations. In this review article, we offer a conceptual overview of applying Bayesian optimization techniques towards solving optimization problems in accelerator physics. We begin by providing a straightforward explanation of the essential components that make up Bayesian optimization techniques. We then give an overview of current and previous work applying and modifying these techniques to solve accelerator physics challenges. Finally, we explore practical implementation strategies for Bayesian optimization algorithms to maximize their performance, enabling users to effectively address complex optimization challenges in real-time beam control and accelerator design.
ISSN:2331-8422
DOI:10.48550/arxiv.2312.05667