Robust discretization and solvers for elliptic optimal control problems with energy regularization
Abstract
We consider the finite element discretization and the iterative solution of singularly perturbed elliptic reaction-diffusion equations in three-dimensional computational domains. These equations arise from the optimality conditions for elliptic distributed optimal control problems with energy regularization that were recently studied by M.~Neum\"{u}ller and O.~Steinbach (2020). We provide quasi-optimal a priori finite element error estimates which depend both on the mesh size and on the regularization parameter . The choice ensures optimal convergence which only depends on the regularity of the target function. For the iterative solution, we employ an algebraic multigrid preconditioner and a balancing domain decomposition by constraints (BDDC) preconditioner. We numerically study robustness and efficiency of the proposed algebraic preconditioners with respect to the mesh size , the regularization parameter , and the number of subdomains (cores) . Furthermore, we investigate the parallel performance of the BDDC preconditioned conjugate gradient solver.
Cite
@article{arxiv.2102.03515,
title = {Robust discretization and solvers for elliptic optimal control problems with energy regularization},
author = {Ulrich Langer and Olaf Steinbach and Huidong Yang},
journal= {arXiv preprint arXiv:2102.03515},
year = {2021}
}