Physics model-informed Gaussian process for online optimization of particle accelerators

Physics model-informed Gaussian process for online optimization of particle accelerators

High-dimensional optimization is a critical challenge for operating large-scale scientific facilities. We apply a physics-informed Gaussian process (GP) optimizer to tune a complex system. Typical GP models learn from past observations to make predictions, but this reduces their applicability to sys...

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Main Authors: Adi Hanuka, X. Huang, J. Shtalenkova, D. Kennedy, A. Edelen, Z. Zhang, V. R. Lalchand, D. Ratner, J. Duris
Format: Article
Language:English
Published: American Physical Society 2021-07-01
Series:Physical Review Accelerators and Beams
Online Access:http://doi.org/10.1103/PhysRevAccelBeams.24.072802
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spelling doaj-5dc4526ca31c47d595ee0b91ac9fd6c62021-07-08T16:18:56ZengAmerican Physical SocietyPhysical Review Accelerators and Beams2469-98882021-07-0124707280210.1103/PhysRevAccelBeams.24.072802Physics model-informed Gaussian process for online optimization of particle acceleratorsAdi HanukaX. HuangJ. ShtalenkovaD. KennedyA. EdelenZ. ZhangV. R. LalchandD. RatnerJ. DurisHigh-dimensional optimization is a critical challenge for operating large-scale scientific facilities. We apply a physics-informed Gaussian process (GP) optimizer to tune a complex system. Typical GP models learn from past observations to make predictions, but this reduces their applicability to systems where there is limited relevant archive data. Instead, here we use a fast approximate model from physics simulations to design the GP model. The GP is then employed to make inferences from sequential online observations in order to optimize the system. Simulation and experimental studies were carried out to demonstrate the method for online control of a storage ring. Our method is a simple prescription to construct a custom GP model, including correlations between the high-dimensional input space, while encoding the physical response of a system. The ability to inform the machine-learning model with physics, without relying on the availability and range of prior data, may have wide applications in science.http://doi.org/10.1103/PhysRevAccelBeams.24.072802
collection DOAJ
language English
format Article
sources DOAJ
author Adi Hanuka
X. Huang
J. Shtalenkova
D. Kennedy
A. Edelen
Z. Zhang
V. R. Lalchand
D. Ratner
J. Duris
spellingShingle Adi Hanuka
X. Huang
J. Shtalenkova
D. Kennedy
A. Edelen
Z. Zhang
V. R. Lalchand
D. Ratner
J. Duris
Physics model-informed Gaussian process for online optimization of particle accelerators
Physical Review Accelerators and Beams
author_facet Adi Hanuka
X. Huang
J. Shtalenkova
D. Kennedy
A. Edelen
Z. Zhang
V. R. Lalchand
D. Ratner
J. Duris
author_sort Adi Hanuka
title Physics model-informed Gaussian process for online optimization of particle accelerators
title_short Physics model-informed Gaussian process for online optimization of particle accelerators
title_full Physics model-informed Gaussian process for online optimization of particle accelerators
title_fullStr Physics model-informed Gaussian process for online optimization of particle accelerators
title_full_unstemmed Physics model-informed Gaussian process for online optimization of particle accelerators
title_sort physics model-informed gaussian process for online optimization of particle accelerators
publisher American Physical Society
series Physical Review Accelerators and Beams
issn 2469-9888
publishDate 2021-07-01
description High-dimensional optimization is a critical challenge for operating large-scale scientific facilities. We apply a physics-informed Gaussian process (GP) optimizer to tune a complex system. Typical GP models learn from past observations to make predictions, but this reduces their applicability to systems where there is limited relevant archive data. Instead, here we use a fast approximate model from physics simulations to design the GP model. The GP is then employed to make inferences from sequential online observations in order to optimize the system. Simulation and experimental studies were carried out to demonstrate the method for online control of a storage ring. Our method is a simple prescription to construct a custom GP model, including correlations between the high-dimensional input space, while encoding the physical response of a system. The ability to inform the machine-learning model with physics, without relying on the availability and range of prior data, may have wide applications in science.
url http://doi.org/10.1103/PhysRevAccelBeams.24.072802
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AT xhuang physicsmodelinformedgaussianprocessforonlineoptimizationofparticleaccelerators
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AT dkennedy physicsmodelinformedgaussianprocessforonlineoptimizationofparticleaccelerators
AT aedelen physicsmodelinformedgaussianprocessforonlineoptimizationofparticleaccelerators
AT zzhang physicsmodelinformedgaussianprocessforonlineoptimizationofparticleaccelerators
AT vrlalchand physicsmodelinformedgaussianprocessforonlineoptimizationofparticleaccelerators
AT dratner physicsmodelinformedgaussianprocessforonlineoptimizationofparticleaccelerators
AT jduris physicsmodelinformedgaussianprocessforonlineoptimizationofparticleaccelerators
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