English

Learning normal form autoencoders for data-driven discovery of universal,parameter-dependent governing equations

Machine Learning 2021-06-10 v1 Dynamical Systems

Abstract

Complex systems manifest a small number of instabilities and bifurcations that are canonical in nature, resulting in universal pattern forming characteristics as a function of some parametric dependence. Such parametric instabilities are mathematically characterized by their universal un-foldings, or normal form dynamics, whereby a parsimonious model can be used to represent the dynamics. Although center manifold theory guarantees the existence of such low-dimensional normal forms, finding them has remained a long standing challenge. In this work, we introduce deep learning autoencoders to discover coordinate transformations that capture the underlying parametric dependence of a dynamical system in terms of its canonical normal form, allowing for a simple representation of the parametric dependence and bifurcation structure. The autoencoder constrains the latent variable to adhere to a given normal form, thus allowing it to learn the appropriate coordinate transformation. We demonstrate the method on a number of example problems, showing that it can capture a diverse set of normal forms associated with Hopf, pitchfork, transcritical and/or saddle node bifurcations. This method shows how normal forms can be leveraged as canonical and universal building blocks in deep learning approaches for model discovery and reduced-order modeling.

Keywords

Cite

@article{arxiv.2106.05102,
  title  = {Learning normal form autoencoders for data-driven discovery of universal,parameter-dependent governing equations},
  author = {Manu Kalia and Steven L. Brunton and Hil G. E. Meijer and Christoph Brune and J. Nathan Kutz},
  journal= {arXiv preprint arXiv:2106.05102},
  year   = {2021}
}

Comments

18 pages, 7 figures

R2 v1 2026-06-24T03:00:39.497Z