English

Robust finite element solvers for distributed hyperbolic optimal control problems

Numerical Analysis 2024-04-08 v1 Numerical Analysis Optimization and Control

Abstract

We propose, analyze, and test new robust iterative solvers for systems of linear algebraic equations arising from the space-time finite element discretization of reduced optimality systems defining the approximate solution of hyperbolic distributed, tracking-type optimal control problems with both the standard L2L^2 and the more general energy regularizations. In contrast to the usual time-stepping approach, we discretize the optimality system by space-time continuous piecewise-linear finite element basis functions which are defined on fully unstructured simplicial meshes. If we aim at the asymptotically best approximation of the given desired state ydy_d by the computed finite element state yϱhy_{\varrho h}, then the optimal choice of the regularization parameter ϱ\varrho is linked to the space-time finite element mesh-size hh by the relations ϱ=h4\varrho=h^4 and ϱ=h2\varrho=h^2 for the L2L^2 and the energy regularization, respectively. For this setting, we can construct robust (parallel) iterative solvers for the reduced finite element optimality systems. These results can be generalized to variable regularization parameters adapted to the local behavior of the mesh-size that can heavily change in the case of adaptive mesh refinements. The numerical results illustrate the theoretical findings firmly.

Keywords

Cite

@article{arxiv.2404.03756,
  title  = {Robust finite element solvers for distributed hyperbolic optimal control problems},
  author = {Ulrich Langer and Richard Löscher and Olaf Steinbach and Huidong Yang},
  journal= {arXiv preprint arXiv:2404.03756},
  year   = {2024}
}
R2 v1 2026-06-28T15:44:36.667Z