English

Robust finite element discretization and solvers for distributed elliptic optimal control problems

Numerical Analysis 2022-07-12 v1 Numerical Analysis Optimization and Control

Abstract

We consider standard tracking-type, distributed elliptic optimal control problems with L2L^2 regularization, and their finite element discretization. We are investigating the L2L^2 error between the finite element approximation uϱhu_{\varrho h} of the state uϱu_\varrho and the desired state (target) uˉ\bar{u} in terms of the regularization parameter ϱ\varrho and the mesh size hh that leads to the optimal choice ϱ=h4\varrho = h^4. It turns out that, for this choice of the regularization parameter, we can devise simple Jacobi-like preconditioned MINRES or Bramble-Pasciak CG methods that allow us to solve the reduced discrete optimality system in asymptotically optimal complexity with respect to the arithmetical operations and memory demand. The theoretical results are confirmed by several benchmark problems with targets of various regularities including discontinuous targets.

Keywords

Cite

@article{arxiv.2207.04664,
  title  = {Robust finite element discretization and solvers for distributed elliptic optimal control problems},
  author = {Ulrich Langer and Richard Löscher and Olaf Steinbach and Huidong Yang},
  journal= {arXiv preprint arXiv:2207.04664},
  year   = {2022}
}
R2 v1 2026-06-25T00:48:08.231Z