# Model reduction of dynamical systems on nonlinear manifolds using deep   convolutional autoencoders

**Authors:** Kookjin Lee, Kevin Carlberg

arXiv: 1812.08373 · 2019-06-07

## TL;DR

This paper introduces a novel nonlinear manifold projection framework for dynamical systems using deep convolutional autoencoders, overcoming limitations of traditional linear subspace methods especially for advection-dominated problems.

## Contribution

It proposes a new approach combining manifold projection with deep autoencoders, providing theoretical analysis and error bounds, and demonstrating superior performance on benchmark problems.

## Key findings

- Outperforms linear subspace ROMs on advection-dominated problems
- Provides a posteriori error bounds for the proposed methods
- Uses deep convolutional autoencoders to efficiently compute nonlinear manifolds

## Abstract

Nearly all model-reduction techniques project the governing equations onto a linear subspace of the original state space. Such subspaces are typically computed using methods such as balanced truncation, rational interpolation, the reduced-basis method, and (balanced) POD. Unfortunately, restricting the state to evolve in a linear subspace imposes a fundamental limitation to the accuracy of the resulting reduced-order model (ROM). In particular, linear-subspace ROMs can be expected to produce low-dimensional models with high accuracy only if the problem admits a fast decaying Kolmogorov $n$-width (e.g., diffusion-dominated problems). Unfortunately, many problems of interest exhibit a slowly decaying Kolmogorov $n$-width (e.g., advection-dominated problems). To address this, we propose a novel framework for projecting dynamical systems onto nonlinear manifolds using minimum-residual formulations at the time-continuous and time-discrete levels; the former leads to manifold Galerkin projection, while the latter leads to manifold least-squares Petrov--Galerkin (LSPG) projection. We perform analyses that provide insight into the relationship between these proposed approaches and classical linear-subspace reduced-order models; we also derive a posteriori discrete-time error bounds for the proposed approaches. In addition, we propose a computationally practical approach for computing the nonlinear manifold, which is based on convolutional autoencoders from deep learning. Finally, we demonstrate the ability of the method to significantly outperform even the optimal linear-subspace ROM on benchmark advection-dominated problems, thereby demonstrating the method's ability to overcome the intrinsic $n$-width limitations of linear subspaces.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1812.08373/full.md

## Figures

47 figures with captions in the complete paper: https://tomesphere.com/paper/1812.08373/full.md

## References

79 references — full list in the complete paper: https://tomesphere.com/paper/1812.08373/full.md

---
Source: https://tomesphere.com/paper/1812.08373