Tsogtgerel Gantumur
Published 2014-03-04, updated 2014-10-02Version 3
In the first part of this paper, we establish a *conditional* optimality result for an adaptive mixed finite element method for the stationary Stokes problem discretized by the standard Taylor-Hood elements, under the assumption of the so-called general quasi-orthogonality. Optimality is measured in terms of a modified approximation class defined through the total error, as is customary since the seminal work of Cascon, Kreuzer, Nochetto and Siebert. The second part of the paper is independent of optimality results, and concerns interrelations between the modified approximation classes and the standard approximation classes (the latter defined through the energy error). Building on the tools developed in the papers of Binev, Dahmen, DeVore, and Petrushev, and of Gaspoz and Morin, we prove that the modified approximation class coincides with the standard approximation class, modulo the assumption that the data is regular enough in an appropriate scale of Besov spaces.
Comments: A gap has been found in the argument we had used in the previous version of this paper, and so one of the main theorems has lost its foundation. The current version is a modification of the paper so that the aforementioned theorem is stated as a conditional result. The other result on approximation classes is still valid, as it is independent of the rest of the paper. 24 pages, 1 figure
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