English

Adaptive least-squares space-time finite element methods

Numerical Analysis 2023-09-26 v1 Numerical Analysis

Abstract

We consider the numerical solution of an abstract operator equation Bu=fBu=f by using a least-squares approach. We assume that B:XYB: X \to Y^* is an isomorphism, and that A:YYA : Y \to Y^* implies a norm in YY, where XX and YY are Hilbert spaces. The minimizer of the least-squares functional 12BufA12\frac{1}{2} \, \| Bu-f \|_{A^{-1}}^2, i.e., the solution of the operator equation, is then characterized by the gradient equation Su=BA1fSu=B^* A^{-1}f with an elliptic and self-adjoint operator S:=BA1B:XXS:=B^* A^{-1} B : X \to X^*. When introducing the adjoint p=A1(fBu)p = A^{-1}(f-Bu) we end up with a saddle point formulation to be solved numerically by using a mixed finite element method. Based on a discrete inf-sup stability condition we derive related a priori error estimates. While the adjoint pp is zero by construction, its approximation php_h serves as a posteriori error indicator to drive an adaptive scheme when discretized appropriately. While this approach can be applied to rather general equations, here we consider second order linear partial differential equations, including the Poisson equation, the heat equation, and the wave equation, in order to demonstrate its potential, which allows to use almost arbitrary space-time finite element methods for the adaptive solution of time-dependent partial differential equations.

Keywords

Cite

@article{arxiv.2309.14300,
  title  = {Adaptive least-squares space-time finite element methods},
  author = {Christian Köthe and Richard Löscher and Olaf Steinbach},
  journal= {arXiv preprint arXiv:2309.14300},
  year   = {2023}
}
R2 v1 2026-06-28T12:31:50.178Z