We present a principled data-driven strategy for learning deterministic hydrodynamic models directly from stochastic non-equilibrium active particle trajectories. We apply our method to learning a hydrodynamic model for the propagating density lanes observed in self-propelled particle systems and to learning a continuum description of cell dynamics in epithelial tissues. We also infer from stochastic particle trajectories the latent phoretic fields driving chemotaxis. This demonstrates that statistical learning theory combined with physical priors can enable discovery of multi-scale models of non-equilibrium stochastic processes characteristic of collective movement in living systems.
%0 Report
%1 117193a50b954d9c8574cc4d7abd7623
%A Maddu, Suryanarayana
%A Vagne, Quentin
%A Sbalzarini, Ivo F.
%D 2022
%K FIS_scads topic_lifescience yaff xack
%R 10.48550/arXiv.2201.08623
%T Learning deterministic hydrodynamic equations from stochastic active particle dynamics
%X We present a principled data-driven strategy for learning deterministic hydrodynamic models directly from stochastic non-equilibrium active particle trajectories. We apply our method to learning a hydrodynamic model for the propagating density lanes observed in self-propelled particle systems and to learning a continuum description of cell dynamics in epithelial tissues. We also infer from stochastic particle trajectories the latent phoretic fields driving chemotaxis. This demonstrates that statistical learning theory combined with physical priors can enable discovery of multi-scale models of non-equilibrium stochastic processes characteristic of collective movement in living systems.
@techreport{117193a50b954d9c8574cc4d7abd7623,
abstract = { We present a principled data-driven strategy for learning deterministic hydrodynamic models directly from stochastic non-equilibrium active particle trajectories. We apply our method to learning a hydrodynamic model for the propagating density lanes observed in self-propelled particle systems and to learning a continuum description of cell dynamics in epithelial tissues. We also infer from stochastic particle trajectories the latent phoretic fields driving chemotaxis. This demonstrates that statistical learning theory combined with physical priors can enable discovery of multi-scale models of non-equilibrium stochastic processes characteristic of collective movement in living systems. },
added-at = {2024-11-28T16:27:18.000+0100},
author = {Maddu, Suryanarayana and Vagne, Quentin and Sbalzarini, {Ivo F.}},
biburl = {https://puma.scadsai.uni-leipzig.de/bibtex/2cf92201a4e8404982a70cb4ce47eb4f4/scadsfct},
day = 21,
doi = {10.48550/arXiv.2201.08623},
interhash = {6adb27071dacc30cf27de48e55950caf},
intrahash = {cf92201a4e8404982a70cb4ce47eb4f4},
keywords = {FIS_scads topic_lifescience yaff xack},
language = {English},
month = jan,
timestamp = {2025-07-29T10:29:54.000+0200},
title = {Learning deterministic hydrodynamic equations from stochastic active particle dynamics},
type = {WorkingPaper},
year = 2022
}
