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Physics-based deep neural networks for beam dynamics in charged particle accelerators

Andrei Ivanov, Ilya Agapov

2020Physical Review Accelerators and Beams28 citationsDOIOpen Access PDF

Abstract

This paper presents a novel approach for constructing neural networks which model charged particle beam dynamics. In our approach, the Taylor maps arising in the representation of dynamics are mapped onto the weights of a polynomial neural network. The resulting network approximates the dynamical system with perfect accuracy prior to training and provides a possibility to tune the network weights on additional experimental data. We propose a symplectic regularization approach for such polynomial neural networks that always restricts the trained model to Hamiltonian systems and significantly improves the training procedure. The proposed networks can be used for beam dynamics simulations or for fine-tuning of beam optics models with experimental data. The structure of the network allows for the modeling of large accelerators with a large number of magnets. We demonstrate our approach on the examples of the existing PETRA III and the planned PETRA IV storage rings at DESY.

Topics & Concepts

Artificial neural networkRegularization (linguistics)Symplectic geometryCharged particlePhysicsComputer scienceBeam (structure)Deep neural networksHamiltonian mechanicsParticle acceleratorRepresentation (politics)Charged particle beamHamiltonian (control theory)PolynomialParticle beamCollisionHamiltonian systemAlgorithmDynamical systems theoryStatistical physicsTaylor seriesBackpropagationClassical mechanicsDeep learningParticle Accelerators and Free-Electron LasersComputational Physics and Python ApplicationsParticle accelerators and beam dynamics
Physics-based deep neural networks for beam dynamics in charged particle accelerators | Litcius