Dictionary-based model reduction for state estimation
Abstract
We consider the problem of state estimation from a few linear measurements, where the state to recover is an element of the manifold of solutions of a parameter-dependent equation. The state is estimated using prior knowledge on coming from model order reduction. Variational approaches based on linear approximation of , such as PBDW, yields a recovery error limited by the Kolmogorov width of . To overcome this issue, piecewise-affine approximations of have also been considered, that consist in using a library of linear spaces among which one is selected by minimizing some distance to . In this paper, we propose a state estimation method relying on dictionary-based model reduction, where a space is selected from a library generated by a dictionary of snapshots, using a distance to the manifold. The selection is performed among a set of candidate spaces obtained from a set of -regularized least-squares problems. Then, in the framework of parameter-dependent operator equations (or PDEs) with affine parametrizations, we provide an efficient offline-online decomposition based on randomized linear algebra, that ensures efficient and stable computations while preserving theoretical guarantees.
Cite
@article{arxiv.2303.10771,
title = {Dictionary-based model reduction for state estimation},
author = {Anthony Nouy and Alexandre Pasco},
journal= {arXiv preprint arXiv:2303.10771},
year = {2024}
}
Comments
29 pages, 7 figures