Goal-oriented error control of the iterative solution of finite element equations
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D. Meidner
Abstract
This paper develops a combined a posteriori analysis for the discretization and iteration errors in the computation of finite element approximations to elliptic boundary value problems. The emphasis is on the multigrid method, but for comparison also simple iterative schemes such as the Gauß–Seidel and the conjugate gradient method are considered. The underlying theoretical framework is that of the Dual Weighted Residual (DWR) method for goal-oriented error estimation. On the basis of these a posteriori error estimates the algebraic iteration can be adjusted to the discretization within a successive mesh adaptation process. The efficiency of the proposed method is demonstrated for several model situations including the simple Poisson equation, the Stokes equations in fluid mechanics and the KKT system of linear-quadratic elliptic optimal control problems.
© de Gruyter 2009
Artikel in diesem Heft
- Error estimates for a finite element solution of the diffusion equation based on composite norms
- A regularization method for polynomial approximation of functions from their approximate values at nodes
- Nonconforming spectral/hp element methods for elliptic systems
- Goal-oriented error control of the iterative solution of finite element equations
Artikel in diesem Heft
- Error estimates for a finite element solution of the diffusion equation based on composite norms
- A regularization method for polynomial approximation of functions from their approximate values at nodes
- Nonconforming spectral/hp element methods for elliptic systems
- Goal-oriented error control of the iterative solution of finite element equations
