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Auteurs principaux: Chen, Siyuan, Wang, Zhecheng, Chen, Yixin, Chang, Yue, Chen, Peter Yichen, Grinspun, Eitan, Panuelos, Jonathan
Format: Preprint
Publié: 2026
Sujets:
Accès en ligne:https://arxiv.org/abs/2603.10995
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author Chen, Siyuan
Wang, Zhecheng
Chen, Yixin
Chang, Yue
Chen, Peter Yichen
Grinspun, Eitan
Panuelos, Jonathan
author_facet Chen, Siyuan
Wang, Zhecheng
Chen, Yixin
Chang, Yue
Chen, Peter Yichen
Grinspun, Eitan
Panuelos, Jonathan
contents A data-driven, model-free approach to modeling the temporal evolution of physical systems mitigates the need for explicit knowledge of the governing equations. Even when physical priors such as partial differential equations are available, such systems often reside in high-dimensional state spaces and exhibit nonlinear dynamics, making traditional numerical solvers computationally expensive and ill-suited for real-time analysis and control. Consider the problem of learning a parametric flow of a dynamical system: with an initial field and a set of physical parameters, we aim to predict the system's evolution over time in a way that supports long-horizon rollouts, generalization to unseen parameters, and spectral analysis. We propose a physics-coded neural field parameterization of the Koopman operator's spectral decomposition. Unlike a physics-constrained neural field, which fits a single solution surface, and neural operators, which directly approximate the solution operator at fixed time horizons, our model learns a factorized flow operator that decouples spatial modes and temporal evolution. This structure exposes underlying eigenvalues, modes, and stability of the underlying physical process to enable stable long-term rollouts, interpolation across parameter spaces, and spectral analysis. We demonstrate the efficacy of our method on a range of dynamics problems, showcasing its ability to accurately predict complex spatiotemporal phenomena while providing insights into the system's dynamic behavior.
format Preprint
id arxiv_https___arxiv_org_abs_2603_10995
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Factorized Neural Implicit DMD for Parametric Dynamics
Chen, Siyuan
Wang, Zhecheng
Chen, Yixin
Chang, Yue
Chen, Peter Yichen
Grinspun, Eitan
Panuelos, Jonathan
Machine Learning
A data-driven, model-free approach to modeling the temporal evolution of physical systems mitigates the need for explicit knowledge of the governing equations. Even when physical priors such as partial differential equations are available, such systems often reside in high-dimensional state spaces and exhibit nonlinear dynamics, making traditional numerical solvers computationally expensive and ill-suited for real-time analysis and control. Consider the problem of learning a parametric flow of a dynamical system: with an initial field and a set of physical parameters, we aim to predict the system's evolution over time in a way that supports long-horizon rollouts, generalization to unseen parameters, and spectral analysis. We propose a physics-coded neural field parameterization of the Koopman operator's spectral decomposition. Unlike a physics-constrained neural field, which fits a single solution surface, and neural operators, which directly approximate the solution operator at fixed time horizons, our model learns a factorized flow operator that decouples spatial modes and temporal evolution. This structure exposes underlying eigenvalues, modes, and stability of the underlying physical process to enable stable long-term rollouts, interpolation across parameter spaces, and spectral analysis. We demonstrate the efficacy of our method on a range of dynamics problems, showcasing its ability to accurately predict complex spatiotemporal phenomena while providing insights into the system's dynamic behavior.
title Factorized Neural Implicit DMD for Parametric Dynamics
topic Machine Learning
url https://arxiv.org/abs/2603.10995