A Relaxed Localized Trust-Region Reduced Basis Approach for Optimization of Multiscale Problems

Keil Tim, Ohlberger Mario

Research article (journal) | Peer reviewed

Abstract

In this contribution, we are concerned with parameter optimization problems that are constrained by multiscale PDE state equations. As an efficient numerical solution approach for such problems, we introduce and analyze a new relaxed and localized trust-region reduced basis method. Localization is obtained based on a Petrov-Galerkin localized orthogonal decomposition method and its recently introduced two-scale reduced basis approximation. We derive efficient localizable a posteriori error estimates for the optimality system, as well as for the two-scale reduced objective functional. While the relaxation of the outer trust-region optimization loop still allows for a rigorous convergence result, the resulting method converges much faster due to larger step sizes in the initial phase of the iterative algorithms. The resulting algorithm is parallelized in order to take advantage of the localization. Numerical experiments are given for a multiscale thermal block benchmark problem. The experiments demonstrate the efficiency of the approach, particularly for large scale problems, where methods based on traditional finite element approximation schemes are prohibitive or fail entirely.

Details about the publication

JournalESAIM: Mathematical Modelling and Numerical Analysis
Volume58
Page range79-105
StatusPublished
Release year2024 (16/01/2024)
Language in which the publication is writtenEnglish
DOI: 10.1051/m2an/2023089
Link to the full texthttps://doi.org/10.1051/m2an/2023089
KeywordsPDE constrained optimization; relaxed trust-region method; localized orthogonal decomposition; twoscale reduced basis approximation; multiscale optimization problems

Authors from the University of Münster

Keil, Tim
Institute for Analysis and Numerics
Ohlberger, Mario
Professorship of Applied Mathematics, especially Numerics (Prof. Ohlberger)
Center for Nonlinear Science
Center for Multiscale Theory and Computation