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Main Authors: Lanza, Alvaro, Qu, Xiang, Bo, Stefano
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.09422
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author Lanza, Alvaro
Qu, Xiang
Bo, Stefano
author_facet Lanza, Alvaro
Qu, Xiang
Bo, Stefano
contents Diffusive dynamics abound in nature and have been especially studied in physical, biological, and financial systems. These dynamics are characterised by a linear growth of the mean squared displacement (MSD) with time. Often, the conditions that give rise to simple diffusion are violated, and many systems, such as biomolecules inside cells, microswimmers, or particles in turbulent flows, undergo anomalous diffusion, featuring an MSD that grows following a power law with an exponent $α$. Precisely determining this exponent and the generalised diffusion coefficient provides valuable information on the systems under consideration, but it is a very challenging task when only a few short trajectories are available, which is common in non-equilibrium and living systems. Estimating the exponent becomes overwhelmingly difficult when the diffusive dynamics switches between different behaviours, characterised by different exponents $α$ or diffusion coefficients $K$. We develop a method based on recurrent neural networks that successfully estimates the anomalous diffusion exponents and generalised diffusion coefficients of individual trajectories that switch between multiple diffusive states. Our method returns the $α$ and $K$ as a function of time and identifies the times at which the dynamics switches between different behaviours. We showcase the method's capabilities on the dataset of the 2024 Anomalous Diffusion Challenge.
format Preprint
id arxiv_https___arxiv_org_abs_2503_09422
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Recurrent neural network analysis of single trajectories switching between anomalous diffusion states
Lanza, Alvaro
Qu, Xiang
Bo, Stefano
Statistical Mechanics
Diffusive dynamics abound in nature and have been especially studied in physical, biological, and financial systems. These dynamics are characterised by a linear growth of the mean squared displacement (MSD) with time. Often, the conditions that give rise to simple diffusion are violated, and many systems, such as biomolecules inside cells, microswimmers, or particles in turbulent flows, undergo anomalous diffusion, featuring an MSD that grows following a power law with an exponent $α$. Precisely determining this exponent and the generalised diffusion coefficient provides valuable information on the systems under consideration, but it is a very challenging task when only a few short trajectories are available, which is common in non-equilibrium and living systems. Estimating the exponent becomes overwhelmingly difficult when the diffusive dynamics switches between different behaviours, characterised by different exponents $α$ or diffusion coefficients $K$. We develop a method based on recurrent neural networks that successfully estimates the anomalous diffusion exponents and generalised diffusion coefficients of individual trajectories that switch between multiple diffusive states. Our method returns the $α$ and $K$ as a function of time and identifies the times at which the dynamics switches between different behaviours. We showcase the method's capabilities on the dataset of the 2024 Anomalous Diffusion Challenge.
title Recurrent neural network analysis of single trajectories switching between anomalous diffusion states
topic Statistical Mechanics
url https://arxiv.org/abs/2503.09422