Non-intrusive reduced-order modeling for dynamical systems with spatially localized features

TL;DR

This paper introduces a hybrid non-intrusive reduced-order modeling framework combining Operator Inference and sparse full-order models, tailored for dynamical systems with spatially localized features and slow singular value decay, enabling fast and accurate predictions.

Contribution

It develops a coupled OpInf-sFOM approach with a novel regularization technique and data-driven subdomain selection, improving efficiency and stability in reduced-order modeling of complex systems.

Findings

Achieves about 1% prediction error on ice thickness dynamics

Provides an 8x online speedup over full simulations

Demonstrates accurate extrapolation beyond training data

Abstract

This work presents a non-intrusive reduced-order modeling framework for dynamical systems with spatially localized features characterized by slow singular value decay. The proposed approach builds upon two existing methodologies for reduced and full-order non-intrusive modeling, namely Operator Inference (OpInf) and sparse Full-Order Model (sFOM) inference. We decompose the domain into two complementary subdomains that exhibit fast and slow singular value decay. The dynamics of the subdomain exhibiting slow singular value decay are learned with sFOM while the dynamics with intrinsically low dimensionality on the complementary subdomain are learned with OpInf. The resulting, coupled OpInf-sFOM formulation leverages the computational efficiency of OpInf and the high resolution of sFOM, and thus enables fast non-intrusive predictions for conditions beyond those sampled in the training data set. A novel regularization technique with a closed-form solution based on the Gershgorin disk theorem is introduced to promote stable sFOM and OpInf models. We also provide a data-driven indicator for subdomain selection and ensure solution smoothness over the interface via a post-processing interpolation step. We evaluate the efficiency of the approach in terms of offline and online speedup through a quantitative, parametric computational cost analysis. We demonstrate the coupled OpInf-sFOM formulation for two test cases: a one-dimensional Burgers' model for which accurate predictions beyond the span of the training snapshots are presented, and a two-dimensional parametric model for the Pine Island Glacier ice thickness dynamics, for which the OpInf-sFOM model achieves an average prediction error on the order of $1 \%$ with an online speedup factor of approximately $8\times$ compared to the numerical simulation.