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Meta-learning Structure-Preserving Dynamics

Machine Learning 2026-05-05 v2

Abstract

Structure-preserving approaches to dynamics discovery have demonstrated great potential for modeling physical systems due to their use of strong inductive biases, which enforce key features such as conservation laws and dissipative behavior. However, these models are typically trained on a per-configuration basis, requiring explicit knowledge of system parameters and costly retraining when these parameters vary. While meta-learning provides a potential remedy, optimization-based approaches can suffer from limited generalizability. Motivated by recent advances in modulation-based learning aimed at mitigating these drawbacks, we systematically investigate the use of modulation techniques in learning conservative dynamical systems. We study a range of existing modulation strategies alongside newly proposed variants, integrating them into a Hamiltonian learning framework without requiring an explicit system parameterization. Through extensive experiments on benchmark problems, we demonstrate that modulation-based meta-learning enables accurate few-shot adaptation, achieving robust generalization across parameter space without compromising the conservation of key invariants responsible for the dynamics.

Keywords

Cite

@article{arxiv.2508.11205,
  title  = {Meta-learning Structure-Preserving Dynamics},
  author = {Cheng Jing and Uvini Balasuriya Mudiyanselage and Woojin Cho and Minju Jo and Anthony Gruber and Kookjin Lee},
  journal= {arXiv preprint arXiv:2508.11205},
  year   = {2026}
}

Comments

Accepted to ICML 2026; full camera-ready version will be updated later

R2 v1 2026-07-01T04:51:04.965Z