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Projected Neural Differential Equations for Learning Constrained Dynamics

Machine Learning 2024-11-01 v1 Computational Physics Machine Learning

Abstract

Neural differential equations offer a powerful approach for learning dynamics from data. However, they do not impose known constraints that should be obeyed by the learned model. It is well-known that enforcing constraints in surrogate models can enhance their generalizability and numerical stability. In this paper, we introduce projected neural differential equations (PNDEs), a new method for constraining neural differential equations based on projection of the learned vector field to the tangent space of the constraint manifold. In tests on several challenging examples, including chaotic dynamical systems and state-of-the-art power grid models, PNDEs outperform existing methods while requiring fewer hyperparameters. The proposed approach demonstrates significant potential for enhancing the modeling of constrained dynamical systems, particularly in complex domains where accuracy and reliability are essential.

Keywords

Cite

@article{arxiv.2410.23667,
  title  = {Projected Neural Differential Equations for Learning Constrained Dynamics},
  author = {Alistair White and Anna Büttner and Maximilian Gelbrecht and Valentin Duruisseaux and Niki Kilbertus and Frank Hellmann and Niklas Boers},
  journal= {arXiv preprint arXiv:2410.23667},
  year   = {2024}
}

Comments

17 pages, 6 figures

R2 v1 2026-06-28T19:42:27.048Z