Gaussian approximation of dynamic cavity equations for linearly-coupled stochastic dynamics

Tarabolo, Mattia; Dall'Asta, Luca

doi:10.21468/SciPostPhys.19.1.019

SciPost Physics

Gaussian approximation of dynamic cavity equations for linearly-coupled stochastic dynamics

Mattia Tarabolo, Luca Dall'Asta

SciPost Phys. 19, 019 (2025) · published 17 July 2025

doi: 10.21468/SciPostPhys.19.1.019
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Abstract

Stochastic dynamics on sparse graphs and disordered systems often lead to complex behaviors characterized by heterogeneity in time and spatial scales, slow relaxation, localization, and aging phenomena. The mathematical tools and approximation techniques required to analyze these complex systems are still under development, posing significant technical challenges and resulting in a reliance on numerical simulations. We introduce a novel computational framework for investigating the dynamics of sparse disordered systems with continuous degrees of freedom. Starting with a graphical model representation of the dynamic partition function for a system of linearly-coupled stochastic differential equations, we use dynamic cavity equations on locally tree-like factor graphs to approximate the stochastic measure. Here, cavity marginals are identified with local functionals of single-site trajectories. Our primary approximation involves a second-order truncation of a small-coupling expansion, leading to a Gaussian form for the cavity marginals. For linear dynamics with additive noise, this method yields a closed set of causal integro-differential equations for cavity versions of one-time and two-time averages. These equations provide an exact dynamical description within the local tree-like approximation, retrieving classical results for the spectral density of sparse random matrices. Global constraints, non-linear forces, and state-dependent noise terms can be addressed using a self-consistent perturbative closure technique. The resulting equations resemble those of dynamical mean-field theory in the mode-coupling approximation used for fully-connected models. However, due to their cavity formulation, the present method can also be applied to ensembles of sparse random graphs and employed as a message-passing algorithm on specific graph instances.

TY  - JOUR
PB  - SciPost Foundation
DO  - 10.21468/SciPostPhys.19.1.019
TI  - Gaussian approximation of dynamic cavity equations for linearly-coupled stochastic dynamics
PY  - 2025/07/17
UR  - https://scipost.org/SciPostPhys.19.1.019
JF  - SciPost Physics
JA  - SciPost Phys.
VL  - 19
IS  - 1
SP  - 019
A1  - Tarabolo, Mattia
AU  - Dall'Asta, Luca
AB  - Stochastic dynamics on sparse graphs and disordered systems often lead to complex behaviors characterized by heterogeneity in time and spatial scales, slow relaxation, localization, and aging phenomena. The mathematical tools and approximation techniques required to analyze these complex systems are still under development, posing significant technical challenges and resulting in a reliance on numerical simulations. We introduce a novel computational framework for investigating the dynamics of sparse disordered systems with continuous degrees of freedom. Starting with a graphical model representation of the dynamic partition function for a system of linearly-coupled stochastic differential equations, we use dynamic cavity equations on locally tree-like factor graphs to approximate the stochastic measure. Here, cavity marginals are identified with local functionals of single-site trajectories. Our primary approximation involves a second-order truncation of a small-coupling expansion, leading to a Gaussian form for the cavity marginals. For linear dynamics with additive noise, this method yields a closed set of causal integro-differential equations for cavity versions of one-time and two-time averages. These equations provide an exact dynamical description within the local tree-like approximation, retrieving classical results for the spectral density of sparse random matrices. Global constraints, non-linear forces, and state-dependent noise terms can be addressed using a self-consistent perturbative closure technique. The resulting equations resemble those of dynamical mean-field theory in the mode-coupling approximation used for fully-connected models. However, due to their cavity formulation, the present method can also be applied to ensembles of sparse random graphs and employed as a message-passing algorithm on specific graph instances.
ER  -

@Article{10.21468/SciPostPhys.19.1.019,
	title={{Gaussian approximation of dynamic cavity equations for linearly-coupled stochastic dynamics}},
	author={Mattia Tarabolo and Luca Dall'Asta},
	journal={SciPost Phys.},
	volume={19},
	pages={019},
	year={2025},
	publisher={SciPost},
	doi={10.21468/SciPostPhys.19.1.019},
	url={https://scipost.org/10.21468/SciPostPhys.19.1.019},
}

Supplementary Information

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Ontology / Topics

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Correlation functions Disordered systems Out-of-equilibrium systems Quenched disorder Stochastic thermodynamics

Authors / Affiliations: mappings to Contributors and Organizations

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¹ Mattia Tarabolo,
¹ ² ³ Luca Dall'Asta

Funder for the research work leading to this publication

NextGenerationEU