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Autores principales: Zou, Joanna, Lie, Han Cheng, Marzouk, Youssef
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2603.20467
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author Zou, Joanna
Lie, Han Cheng
Marzouk, Youssef
author_facet Zou, Joanna
Lie, Han Cheng
Marzouk, Youssef
contents The governing equations of stochastic dynamical systems often become cost-prohibitive for numerical simulation at large scales. Surrogate models of the governing equations, learned from data of the high-fidelity system, are routinely used to predict key observables with greater efficiency. However, standard choices of loss function for learning the surrogate model fail to provide error guarantees in path-dependent observables, such as reaction rates of molecular dynamical systems. This paper introduces an error bound for path-space observables and employs it as a novel variational loss for the goal-oriented learning of a stochastic dynamical system. We show the error bound holds for a broad class of observables, including mean first hitting times on unbounded time domains. We derive an analytical gradient of the goal-oriented loss function by leveraging the formula for Frechet derivatives of expected path functionals, which remains tractable for implementation in stochastic gradient descent schemes. We demonstrate that surrogate models of overdamped Langevin systems developed via goal-oriented learning achieve improved accuracy in predicting the statistics of a first hitting time observable and robustness to distributional shift in the data.
format Preprint
id arxiv_https___arxiv_org_abs_2603_20467
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Goal-oriented learning of stochastic dynamical systems using error bounds on path-space observables
Zou, Joanna
Lie, Han Cheng
Marzouk, Youssef
Methodology
Machine Learning
Dynamical Systems
60H10, 60H35, 94A15, 62M99
The governing equations of stochastic dynamical systems often become cost-prohibitive for numerical simulation at large scales. Surrogate models of the governing equations, learned from data of the high-fidelity system, are routinely used to predict key observables with greater efficiency. However, standard choices of loss function for learning the surrogate model fail to provide error guarantees in path-dependent observables, such as reaction rates of molecular dynamical systems. This paper introduces an error bound for path-space observables and employs it as a novel variational loss for the goal-oriented learning of a stochastic dynamical system. We show the error bound holds for a broad class of observables, including mean first hitting times on unbounded time domains. We derive an analytical gradient of the goal-oriented loss function by leveraging the formula for Frechet derivatives of expected path functionals, which remains tractable for implementation in stochastic gradient descent schemes. We demonstrate that surrogate models of overdamped Langevin systems developed via goal-oriented learning achieve improved accuracy in predicting the statistics of a first hitting time observable and robustness to distributional shift in the data.
title Goal-oriented learning of stochastic dynamical systems using error bounds on path-space observables
topic Methodology
Machine Learning
Dynamical Systems
60H10, 60H35, 94A15, 62M99
url https://arxiv.org/abs/2603.20467