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A deep learning approach to the measurement of long-lived memory kernels from Generalised Langevin Dynamics

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arxiv 2302.13682 v2 pith:HWUC6YLH submitted 2023-02-27 cond-mat.dis-nn cond-mat.softcond-mat.stat-mech

A deep learning approach to the measurement of long-lived memory kernels from Generalised Langevin Dynamics

classification cond-mat.dis-nn cond-mat.softcond-mat.stat-mech
keywords memoryeffectsdatadeepglassykernelssystemsdescribe
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Memory effects are ubiquitous in a wide variety of complex physical phenomena, ranging from glassy dynamics and metamaterials to climate models. The Generalised Langevin Equation (GLE) provides a rigorous way to describe memory effects via the so-called memory kernel in an integro-differential equation. However, the memory kernel is often unknown, and accurately predicting or measuring it via e.g. a numerical inverse Laplace transform remains a herculean task. Here we describe a novel method using deep neural networks (DNNs) to measure memory kernels from dynamical data. As proof-of-principle, we focus on the notoriously long-lived memory effects of glassy systems, which have proved a major challenge to existing methods. Specifically, we learn a training set generated with the Mode-Coupling Theory (MCT) of hard spheres. Our DNNs are remarkably robust against noise, in contrast to conventional techniques which require ensemble averaging over many independent trajectories. Finally, we demonstrate that a network trained on data generated from analytic theory (hard-sphere MCT) generalises well to data from simulations of a different system (Brownian Weeks-Chandler-Andersen particles). We provide a general pipeline, KernelLearner, for training networks to extract memory kernels from any non-Markovian system described by a GLE. The success of our DNN method applied to glassy systems suggests deep learning can play an important role in the study of dynamical systems that exhibit memory effects.

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