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Main Authors: Germain, Thibaut, Chemlal, Sami, Flamary, Rémi, Kostic, Vladimir R., Lounici, Karim
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.18276
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author Germain, Thibaut
Chemlal, Sami
Flamary, Rémi
Kostic, Vladimir R.
Lounici, Karim
author_facet Germain, Thibaut
Chemlal, Sami
Flamary, Rémi
Kostic, Vladimir R.
Lounici, Karim
contents Learning dynamical systems through operator-theoretic representations provides a powerful framework for analyzing complex dynamics, as spectral quantities such as eigenvalues and invariant structures encode characteristic time scales and long-term behavior. However, dynamical operators are typically estimated independently for each system, preventing the discovery of shared structure across related dynamics. To address this limitation, we posit that related dynamical systems lie near a low-dimensional manifold in spectral operator space. Based on this hypothesis, we introduce DOODL (Dynamical OperatOr Dictionary Learning), a framework that learns a dictionary of characteristic spectral dynamics whose combinations approximate this manifold and yield compact, interpretable embeddings of individual systems. Beyond representation learning, DOODL enables fast and interpretable operator estimation from short and partially observed trajectories by constraining the estimation to the learned operator manifold. Experiments on metastable Langevin dynamics and turbulent plasma simulations demonstrate that DOODL scales to highly complex multiscale regimes while capturing characteristic spectral structure governing the dynamics rather than merely fitting trajectories, achieving errors one to two orders of magnitude lower than independent operator estimation methods in challenging low-data regimes.
format Preprint
id arxiv_https___arxiv_org_abs_2605_18276
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Geometric Dictionary Learning of Dynamical Systems with Optimal Transport
Germain, Thibaut
Chemlal, Sami
Flamary, Rémi
Kostic, Vladimir R.
Lounici, Karim
Machine Learning
Learning dynamical systems through operator-theoretic representations provides a powerful framework for analyzing complex dynamics, as spectral quantities such as eigenvalues and invariant structures encode characteristic time scales and long-term behavior. However, dynamical operators are typically estimated independently for each system, preventing the discovery of shared structure across related dynamics. To address this limitation, we posit that related dynamical systems lie near a low-dimensional manifold in spectral operator space. Based on this hypothesis, we introduce DOODL (Dynamical OperatOr Dictionary Learning), a framework that learns a dictionary of characteristic spectral dynamics whose combinations approximate this manifold and yield compact, interpretable embeddings of individual systems. Beyond representation learning, DOODL enables fast and interpretable operator estimation from short and partially observed trajectories by constraining the estimation to the learned operator manifold. Experiments on metastable Langevin dynamics and turbulent plasma simulations demonstrate that DOODL scales to highly complex multiscale regimes while capturing characteristic spectral structure governing the dynamics rather than merely fitting trajectories, achieving errors one to two orders of magnitude lower than independent operator estimation methods in challenging low-data regimes.
title Geometric Dictionary Learning of Dynamical Systems with Optimal Transport
topic Machine Learning
url https://arxiv.org/abs/2605.18276