Robust space-time finite element error estimates for parabolic distributed optimal control problems with energy regularization

Abstract

We consider space-time tracking optimal control problems for linear para\-bo\-lic initial boundary value problems that are given in the space-time cylinder Q = × (0,T), and that are controlled by the right-hand side z from the Bochner space L2(0,T;H-1()). So it is natural to replace the usual L2(Q) norm regularization by the energy regularization in the L2(0,T;H-1()) norm. We derive a priori estimates for the error \|u h - u\|L2(Q) between the computed state u h and the desired state u in terms of the regularization parameter and the space-time finite element mesh-size h, and depending on the regularity of the desired state u. These estimates lead to the optimal choice = h2. The approximate state u h is computed by means of a space-time finite element method using piecewise linear and continuous basis functions on completely unstructured simplicial meshes for Q. The theoretical results are quantitatively illustrated by a series of numerical examples in two and three space dimensions.