An Online Manifold Learning Approach for Model Reduction of Dynamical Systems

TL;DR

This paper introduces an online manifold learning method called SIRM for efficient, iterative model reduction of dynamical systems, demonstrating its accuracy and computational advantages through various numerical examples.

Contribution

The paper presents a novel online subspace iteration method for model reduction that does not require offline training, with proven convergence and demonstrated effectiveness on complex systems.

Findings

SIRM achieves high accuracy in linear and nonlinear PDEs.

The method converges to the true solution under Lipschitz conditions.

Local SIRM reduces computational cost significantly.

Abstract

This article discusses a newly developed online manifold learning method, subspace iteration using reduced models (SIRM), for the dimensionality reduction of dynamical systems. This method may be viewed as subspace iteration combined with a model reduction procedure. Specifically, starting with a test solution, the method solves a reduced model to obtain a more precise solution, and it repeats this process until sufficient accuracy is achieved. The reduced model is obtained by projecting the full model onto a subspace that is spanned by the dominant modes of an extended data ensemble. The learning procedure is computed in the online stage, as opposed to being computed offline, which is used in many projection-based model reduction techniques that require prior calculations or experiments. After providing an error bound of the classical POD-Galerkin method in terms of the projection error and the initial condition error, we prove that the sequence of approximate solutions converge to the actual solution of the original system as long as the vector field of the full model is locally Lipschitz on an open set that contains the solution trajectory. Good accuracy of the proposed method has been demonstrated in two numerical examples, from a linear advection-diffusion equation to a nonlinear Burgers equation. In order to save computational cost, the SIRM method is extended to a local model reduction approach by partitioning the entire time domain into several subintervals and obtaining a series of local reduced models of much lower dimensionality. The accuracy and efficiency of the local SIRM are shown through the numerical simulation of the Navier--Stokes equation in a lid-driven cavity flow problem.