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Learning nonequilibrium control forces to characterize dynamical phase transitions

Jiawei Yan, Hugo Touchette, Grant M. Rotskoff

2022Physical review. E37 citationsDOIOpen Access PDF

Abstract

Sampling the collective, dynamical fluctuations that lead to nonequilibrium pattern formation requires probing rare regions of trajectory space. Recent approaches to this problem, based on importance sampling, cloning, and spectral approximations, have yielded significant insight into nonequilibrium systems but tend to scale poorly with the size of the system, especially near dynamical phase transitions. Here we propose a machine learning algorithm that samples rare trajectories and estimates the associated large deviation functions using a many-body control force by leveraging the flexible function representation provided by deep neural networks, importance sampling in trajectory space, and stochastic optimal control theory. We show that this approach scales to hundreds of interacting particles and remains robust at dynamical phase transitions.

Topics & Concepts

Non-equilibrium thermodynamicsStatistical physicsPhase spaceTrajectoryDynamical systems theorySampling (signal processing)Representation (politics)PhysicsFunction (biology)Phase transitionDynamical system (definition)Phase (matter)Computer scienceClassical mechanicsQuantum mechanicsDetectorPoliticsBiologyLawOpticsPolitical scienceEvolutionary biologyAdvanced Thermodynamics and Statistical MechanicsNeural dynamics and brain functionStatistical Mechanics and Entropy
Learning nonequilibrium control forces to characterize dynamical phase transitions | Litcius