Data-driven discovery of intrinsic dynamics

TL;DR

This paper introduces a method combining manifold theory and neural networks to discover intrinsic low-dimensional variables driving complex systems from time series data.

Contribution

It develops a novel approach that learns intrinsic state variables and their dynamics directly from data, reducing dimensionality based on manifold structure.

Findings

Successfully applied to high-dimensional systems with low-dimensional behavior

Learns minimal-dimensional models capturing essential dynamics

Outperforms traditional methods in identifying intrinsic variables

Abstract

Dynamical models underpin our ability to understand and predict the behavior of natural systems. Whether dynamical models are developed from first-principles derivations or from observational data, they are predicated on our choice of state variables. The choice of state variables is driven by convenience and intuition, and in the data-driven case the observed variables are often chosen to be the state variables. The dimensionality of these variables (and consequently the dynamical models) can be arbitrarily large, obscuring the underlying behavior of the system. In truth, these variables are often highly redundant and the system is driven by a much smaller set of latent intrinsic variables. In this study, we combine the mathematical theory of manifolds with the representational capacity of neural networks to develop a method that learns a system's intrinsic state variables directly from time series data, and also learns predictive models for their dynamics. What distinguishes our method is its ability to reduce data to the intrinsic dimensionality of the nonlinear manifold they live on. This ability is enabled by the concepts of charts and atlases from the theory of manifolds, whereby a manifold is represented by a collection of patches that are sewn together -- a necessary representation to attain intrinsic dimensionality. We demonstrate this approach on several high-dimensional systems with low-dimensional behavior. The resulting framework provides the ability to develop dynamical models of the lowest possible dimension, capturing the essence of a system.