Multipoint-BAX: a new approach for efficiently tuning particle accelerator emittance via virtual objectives

Ayoub Miskovich, Sara; Neiswanger, Willie; Colocho, William; Emma, Claudio; Garrahan, Jacqueline; Maxwell, Timothy; Mayes, Christopher; Ermon, Stefano; Edelen, Auralee; Ratner, Daniel

doi:10.1088/2632-2153/ad169f

Mach. Learn.: Sci. Technol.

2024

DOI: 10.1088/2632-2153/ad169f

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Multipoint-BAX: a new approach for efficiently tuning particle accelerator emittance via virtual objectives

Sara Ayoub Miskovich,

Willie Neiswanger,

William Colocho

et al.

Abstract: Although beam emittance is critical for the performance of high-brightness accelerators, optimization is often time limited as emittance calculations, commonly done via quadrupole scans, are typically slow. Such calculations are a type of multipoint query, i.e. each query requires multiple secondary measurements. Traditional black-box optimizers such as Bayesian optimization are slow and inefficient when dealing with such objectives as they must acquire the full series of measurements, but return only the emit… Show more

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Targeted materials discovery using Bayesian algorithm execution

Chitturi,

Ramdas,

et al. 2024

npj Comput Mater

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Rapid discovery and synthesis of future materials requires intelligent data acquisition strategies to navigate large design spaces. A popular strategy is Bayesian optimization, which aims to find candidates that maximize material properties; however, materials design often requires finding specific subsets of the design space which meet more complex or specialized goals. We present a framework that captures experimental goals through straightforward user-defined filtering algorithms. These algorithms are automatically translated into one of three intelligent, parameter-free, sequential data collection strategies (SwitchBAX, InfoBAX, and MeanBAX), bypassing the time-consuming and difficult process of task-specific acquisition function design. Our framework is tailored for typical discrete search spaces involving multiple measured physical properties and short time-horizon decision making. We demonstrate this approach on datasets for TiO2 nanoparticle synthesis and magnetic materials characterization, and show that our methods are significantly more efficient than state-of-the-art approaches. Overall, our framework provides a practical solution for navigating the complexities of materials design, and helps lay groundwork for the accelerated development of advanced materials.

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Targeted materials discovery using Bayesian algorithm execution

Chitturi,

Ramdas,

et al. 2024

npj Comput Mater

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Robust errant beam prognostics with conditional modeling for particle accelerators

Rajput,

Schram,

Blokland

et al. 2024

Mach. Learn.: Sci. Technol.

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Particle accelerators are complex and comprise thousands of components, with many pieces of equipment running at their peak power. Consequently, they can fault and abort operations for numerous reasons, lowering efficiency and science output. To avoid these faults, we apply anomaly detection techniques to predict unusual behavior and perform preemptive actions to improve the total availability. Supervised Machine Learning (ML) techniques such as Siamese Neural Network (SNN) models can outperform the often-used unsupervised or semi-supervised approaches for anomaly detection by leveraging the label information. One of the challenges specific to anomaly detection for particle accelerators is the data’s variability due to accelerator configuration changes within a production run of several months. ML models fail at providing accurate predictions when data changes due to changes in the configuration. To address this challenge, we include the configuration settings into our models and training to improve the results. Beam configurations are used as a conditional input for the model to learn any cross-correlation between the data from different conditions and retain its performance. We employ Conditional Siamese Neural Network (CSNN) models and Conditional Variational Auto Encoder (CVAE) models to predict errant beam pulses at the Spallation Neutron Source (SNS) under different system configurations and compare their performance. We demonstrate that CSNNs outperform CVAEs in our application.

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Bayesian optimization algorithms for accelerator physics

Roussel,

Edelen,

Boltz

et al. 2024

Phys. Rev. Accel. Beams

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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 toward 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. Published by the American Physical Society 2024

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Multipoint-BAX: a new approach for efficiently tuning particle accelerator emittance via virtual objectives

Cited by 3 publications

References 49 publications

Targeted materials discovery using Bayesian algorithm execution

Targeted materials discovery using Bayesian algorithm execution

Robust errant beam prognostics with conditional modeling for particle accelerators

Bayesian optimization algorithms for accelerator physics

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