Machine learning for orders of magnitude speedup in multiobjective optimization of particle accelerator systems

Edelen, Auralee; Neveu, Nicole; Frey, Matthias; Huber, Yannick; Mayes, Christopher; Adelmann, Andreas

doi:10.1103/physrevaccelbeams.23.044601

Cited by 96 publications

(101 citation statements)

References 42 publications

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“…ML-based tools, such as neural networks (NN), can be trained to automatically tune and control large complex systems such as particle accelerators [37][38][39][40]. ML tools are being developed to provide surrogate models to create diagnostics [41]. A NN model has been designed to predict the resonant frequency of the radio frequency quadrupole (RFQ) in the PIP-II Injector Experiment (PXIE), to be used in a model predictive control scheme [42].…”

Section: Advanced Control Methodsmentioning

confidence: 99%

Advanced Control Methods for Particle Accelerators (ACM4PA) 2019

Scheinker

Emma

Edelen

et al. 2019

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Los Alamos is currently developing novel particle accelerator controls and diagnostics algorithms to enable higher quality beams with lower beam losses than is currently possible. The purpose of this workshop was to consider tuning and optimization challenges of a wide range of particle accelerators including linear proton accelerators such as the Los Alamos Neutron Science Center (LANSCE), rings such as the Advanced Photon Source (APS) synchrotron, free electron lasers (FEL) such as the Linac Coherent Light Source (LCLS) and LCLS-II, the European X-ray Free Electron Laser (EuXFEL), the Swiss FEL, and the planned MaRIE FEL, and plasma wake-field accelerators such as FACET, FACET-II, and AWAKE at CERN. One major challenge is an the ability to quickly create very high quality, extremely intense, custom current and energy profile beams while working with limited real time non-invasive diagnostics and utilizing time-varying uncertain initial beam distributions and accelerator components. Currently, a few individual accelerator labs have been developing and applying their own diagnostics tools and custom control and ML algorithms for automated machine tuning and optimization. The goal of this workshop was to bring together a group of accelerator physicists and accelerator related control and ML experts in order to define which controls and diagnostics would be most useful for existing and future accelerators and to create a plan for developing a new family of algorithms that can be shared and maintained by the community. Organizing CommitteeAlexander Scheinker LANL

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Section: Advanced Control Methodsmentioning

confidence: 99%

Advanced Control Methods for Particle Accelerators (ACM4PA) 2019

Scheinker

Emma

Edelen

et al. 2019

Self Cite

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“…ML-based tools, such as neural networks (NN), can be trained to automatically tune and control large complex systems such as particle accelerators [45][46][47][48]. ML tools are being developed to provide fast and accurate surrogate models to create diagnostics that enable feedback control and tuning of accelerators [49]. A NN model has been designed to predict the resonant frequency of the radio frequency quadrupole (RFQ) in the PIP-II Injector Experiment (PXIE), to be used in a model predictive control scheme [50].…”

Section: B Machine Learningmentioning

confidence: 99%

Model-independent tuning for maximizing free electron laser pulse energy

Scheinker

Bohler

Tomin

et al. 2019

Phys. Rev. Accel. Beams

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The output power of a free electron laser (FEL) has extremely high variance even when all FEL parameter set points are held constant because of the stochastic nature of the self-amplified spontaneous emission (SASE) FEL process, drift of thousands of coupled parameters, such as thermal drifts, and uncertainty and time variation of the electron distribution coming off of the photo cathode and entering the accelerator. In this work, we demonstrate the application of automatic, model-independent feedback for the maximization of average pulse energy of the light produced by free electron lasers. We present experimental results from both the European x-ray free electron laser at DESY and from the Linac Coherent Light Source at SLAC. We demonstrate application of the technique on rf systems for automatically adjusting the longitudinal phase space of the beam, for adjusting the phase shifter gaps between the undulators, and for adjusting steering magnets between undulator sections to maximize the FEL output power. We show that we can tune up to 105 components simultaneously based only on noisy average bunch energy measurements.

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“…And, a combination of MOGA and MOPSO has more potential of avoiding local optima than using the MOGA or MOPSO alone [12]. Moreover, accelerator scientists are now exploring different machine learning enhanced MOGAs [14][15][16][17][18]. The basic consideration is that the dataset fX n ; Y n g continuously produced and accumulated by the MOGA can be used as the training data of machine learning, so as to reveal some hidden properties of the data which, in turn, helps to speed up the convergence and/or increase the diversity among solutions.…”

Section: Introductionmentioning

confidence: 99%

“…The new competitive offspring individuals are then generated within the elite variable range and used to replace the original data in the population, which can result in faster convergence. Another approach is to use the data from MOGA to train a machine learning surrogate model (e.g., [16,17]), which can predict the objective values in fractions of a second, much faster than the actual evaluator. To take advantage of such a surrogate model, one can use it to replace the actual MOGA evaluator as in Ref.…”

Section: Introductionmentioning

confidence: 99%

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Neural network-based multiobjective optimization algorithm for nonlinear beam dynamics

Wan

Chu

Jiao

2020

Phys. Rev. Accel. Beams

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Multiobjective genetic algorithms (MOGAs) have proven to be powerful in solving multiobjective problems in the accelerator field. Nevertheless, for explorative problems that have many variables and local optima, the performance of MOGAs is not always satisfactory, especially when a small population size is used due to practical limitations, e.g., limited computing resources. To deal with this challenge, in this paper an enhanced MOGA, neural network-based MOGA (NBMOGA), is proposed. In this method, the data produced with the standard MOGA are used to train a neural network. The neural network is fast to produce a large pool of objective function estimates, with sufficiently high accuracy. A subset of the most competitive estimates is selected to form a population (matching MOGA population size), which is then evaluated with the MOGA evaluator. By taking three classic multiobjective problems as examples, we demonstrate that the proposed method promises a faster convergence and a higher degree of diversity than that available with the standard MOGA and other three optimization methods that have been applied in the accelerator field, i.e., the multiobjective particle swarm optimization (MOPSO), the combination of MOPSO and MOGA, and the clustering enhanced MOGA. And then this method is applied to a timeconsuming optimization problem, the dynamic aperture and Touschek lifetime optimization of the high energy photon source. It turns out that, within the same optimization time, a better set of solutions in the objective space can be obtained with the NBMOGA than using other methods. The Touschek lifetime can be improved by about 10% compared with using the standard MOGA, with approximately the same dynamic aperture area. Besides, a higher degree of diversity among solutions is observed with the NBMOGA than using other tested methods.

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Machine learning for orders of magnitude speedup in multiobjective optimization of particle accelerator systems

Cited by 96 publications

References 42 publications

Advanced Control Methods for Particle Accelerators (ACM4PA) 2019

Advanced Control Methods for Particle Accelerators (ACM4PA) 2019

Model-independent tuning for maximizing free electron laser pulse energy

Neural network-based multiobjective optimization algorithm for nonlinear beam dynamics

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