A Basic Convergence Result for Conforming Adaptive Finite Elements

Abstract: Abstract. We consider the approximate solution with adaptive finite elements of a class of linear boundary value problems, which includes problems of 'saddle point' type. For the adaptive algorithm we suppose the following framework: refinement relies on unique quasi-regular element subdivisions and generates locally quasi-uniform grids, the finite element spaces are conforming, nested, and satisfy the inf-sup conditions, the error estimator is reliable as well as locally and discretely efficient, and marked e… Show more

“…where pw, oq P W 1,r 1 0 pΩq dˆLr 1 pΩq{R. Although for the sake of simplicity we restrict ourselves here to residual-based estimates, we note that in principle other a posteriori techniques, such as hierarchical estimates, flux-equilibration or estimates based on local problems, can be used as well; compare with [MSV08,Sie11]. For n P N and G P G let`U n G , P n G˘P VpGqˆQ 0 pGq be the Galerkin approximation defined in (3.20).…”

“…Corollary 22 states the stability properties of the estimator, which are required in order to apply the convergence theory in [Sie11,MSV08]; compare with [Sie11, (2.10b)], for example. The stability of the estimator is also of importance for the efficiency of the estimator.…”

“…The resulting steady non-Newtonian flow problem is then discretized by a mixed finite element method. Guided by an a posteriori error analysis, we propose a numerical method with competing adaptive strategies for the mesh refinement and the approximation of the implicit constitutive law, and we present a rigorous convergence proof generalizing the ideas in [MSV08] and [Sie11]. More precisely, we show that a subsequence of the adaptively generated sequence of discrete approximations converges, in the weak topology of the ambient function space, to a weak solution of the model when 2d…”

Adaptive finite element approximation of steady flows of incompressible fluids with implicit power-law-like rheology

“…where pw, oq P W 1,r 1 0 pΩq dˆLr 1 pΩq{R. Although for the sake of simplicity we restrict ourselves here to residual-based estimates, we note that in principle other a posteriori techniques, such as hierarchical estimates, flux-equilibration or estimates based on local problems, can be used as well; compare with [MSV08,Sie11]. For n P N and G P G let`U n G , P n G˘P VpGqˆQ 0 pGq be the Galerkin approximation defined in (3.20).…”

“…Corollary 22 states the stability properties of the estimator, which are required in order to apply the convergence theory in [Sie11,MSV08]; compare with [Sie11, (2.10b)], for example. The stability of the estimator is also of importance for the efficiency of the estimator.…”

“…The resulting steady non-Newtonian flow problem is then discretized by a mixed finite element method. Guided by an a posteriori error analysis, we propose a numerical method with competing adaptive strategies for the mesh refinement and the approximation of the implicit constitutive law, and we present a rigorous convergence proof generalizing the ideas in [MSV08] and [Sie11]. More precisely, we show that a subsequence of the adaptively generated sequence of discrete approximations converges, in the weak topology of the ambient function space, to a weak solution of the model when 2d…”

Adaptive finite element approximation of steady flows of incompressible fluids with implicit power-law-like rheology

“…The convergence properties of AFEM have become the subject of intense theoretical study only in the past few years, however. We refer to [6,[11][12][13][14] for an overview of progress in basic convergence theory for AFEM for linear elliptic problems. Optimal convergence rates were demonstrated in [4,19].…”

Convergence and quasi-optimality of an adaptive finite element method for controlling L 2 errors

“…The latter work was generalized in various directions. Lately, convergence of adaptive methods with marking strategies other than Dörfler's, for a large class of linear problems with different a posteriori error estimators, and without requiring the marking due to oscillation or the interior node property, was proved in [Morin Siebert Veeser 2007]. The result only leads to asymptotic convergence without an error reduction in every step, which seems to be essential to prove optimality though (see [Stevenson 2006, Cascón et.…”

Convergence rates for adaptive finite elements