English

Scalable nonlinear manifold reduced order model for dynamical systems

Numerical Analysis 2024-12-03 v1 Numerical Analysis Dynamical Systems Computational Physics

Abstract

The domain decomposition (DD) nonlinear-manifold reduced-order model (NM-ROM) represents a computationally efficient method for integrating underlying physics principles into a neural network-based, data-driven approach. Compared to linear subspace methods, NM-ROMs offer superior expressivity and enhanced reconstruction capabilities, while DD enables cost-effective, parallel training of autoencoders by partitioning the domain into algebraic subdomains. In this work, we investigate the scalability of this approach by implementing a "bottom-up" strategy: training NM-ROMs on smaller domains and subsequently deploying them on larger, composable ones. The application of this method to the two-dimensional time-dependent Burgers' equation shows that extrapolating from smaller to larger domains is both stable and effective. This approach achieves an accuracy of 1% in relative error and provides a remarkable speedup of nearly 700 times.

Keywords

Cite

@article{arxiv.2412.00507,
  title  = {Scalable nonlinear manifold reduced order model for dynamical systems},
  author = {Ivan Zanardi and Alejandro N. Diaz and Seung Whan Chung and Marco Panesi and Youngsoo Choi},
  journal= {arXiv preprint arXiv:2412.00507},
  year   = {2024}
}

Comments

To be included in the proceedings of the Machine Learning and the Physical Sciences Workshop at NeurIPS 2024

R2 v1 2026-06-28T20:18:04.321Z