Error analysis of discontinuous Galerkin methods for the Stokes problem under minimum regularity

Revision as of 13:22, 5 September 2019

Abstract

In this article, we analyse several discontinuous Galerkin (DG) methods for the Stokes problem under minimal regularity on the solution. We assume that the velocity u belongs to $[{H}_{0}^{1}(\Omega )]^{d}$ and the pressure $p\in {L}_{0}^{2}(\Omega )$ . First, we analyse standard DG methods assuming that the right-hand side f belongs to $[H^{-1}(\Omega )\cap L^{1}(\Omega )]^{d}$ . A DG method that is well defined for f belonging to $[H^{-1}(\Omega )]^{d}$ is then investigated. The methods under study include stabilized DG methods using equal-order spaces and inf–sup stable ones where the pressure space is one polynomial degree less than the velocity space.

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	== Abstract ==		== Abstract ==

−	In this article, we analyse several discontinuous Galerkin (DG) methods for the Stokes problem under minimal regularity on the solution. We assume that the velocity u belongs to <math>[{H}^1_0(\Omega)]^d and the pressure <math>p\in {L}^2_0(\Omega)</math>. First, we analyse standard DG methods assuming that the right-hand side f belongs to <math>[H^{-1}(\Omega)\cap L^1(\Omega)]^d</math>. A DG method that is well defined for f belonging to <math>[H^{-1}(\Omega)]^d</math> is then investigated. The methods under study include stabilized DG methods using equal-order spaces and inf–sup stable ones where the pressure space is one polynomial degree less than the velocity space.	+	In this article, we analyse several discontinuous Galerkin (DG) methods for the Stokes problem under minimal regularity on the solution. We assume that the velocity u belongs to <math>[{H}^1_0(\Omega)]^d</math> and the pressure <math>p\in {L}^2_0(\Omega)</math>. First, we analyse standard DG methods assuming that the right-hand side f belongs to <math>[H^{-1}(\Omega)\cap L^1(\Omega)]^d</math>. A DG method that is well defined for f belonging to <math>[H^{-1}(\Omega)]^d</math> is then investigated. The methods under study include stabilized DG methods using equal-order spaces and inf–sup stable ones where the pressure space is one polynomial degree less than the velocity space.

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