Learning hydrodynamic equations for active matter from particle simulations and experiments
Abstract
Recent advances in high-resolution imaging techniques and particle-based simulation methods have enabled the precise microscopic characterization of collective dynamics in various biological and engineered active matter systems. In parallel, data-driven algorithms for learning interpretable continuum models have shown promising potential for the recovery of underlying partial differential equations (PDEs) from continuum simulation data. By contrast, learning macroscopic hydrodynamic equations for active matter directly from experiments or particle simulations remains a major challenge. Here, we present a framework that leverages spectral basis representations and sparse regression algorithms to discover PDE models from microscopic simulation and experimental data, while incorporating the relevant physical symmetries. We illustrate the practical potential through applications to a chiral active particle model mimicking swimming cells and to recent microroller experiments. In both cases, our scheme learns hydrodynamic equations that reproduce quantitatively the self-organized collective dynamics observed in the simulations and experiments. This inference framework makes it possible to measure a large number of hydrodynamic parameters in parallel and directly from video data.
Cite
@article{arxiv.2101.06568,
title = {Learning hydrodynamic equations for active matter from particle simulations and experiments},
author = {Rohit Supekar and Boya Song and Alasdair Hastewell and Gary P. T. Choi and Alexander Mietke and Jörn Dunkel},
journal= {arXiv preprint arXiv:2101.06568},
year = {2023}
}
Comments
Added statistical analysis of learned parameters, Added comparison to analytic coarse-graining approaches, Added spectral comparisons, Added framework application on fish data