A new elasticity element made for enforcing weak stress symmetry

Cockburn, Bernardo; Gopalakrishnan, Jayadeep; Guzmán, Johnny

doi:10.1090/S0025-5718-10-02343-4

A new elasticity element made for enforcing weak stress symmetry
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by Bernardo Cockburn, Jayadeep Gopalakrishnan and Johnny Guzmán;

Math. Comp. 79 (2010), 1331-1349

DOI: https://doi.org/10.1090/S0025-5718-10-02343-4

Published electronically: March 12, 2010

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Abstract:

We introduce a new mixed method for linear elasticity. The novelty is a simplicial element for the approximate stress. For every positive integer $k$, the row-wise divergence of the element space spans the set of polynomials of total degree $k$. The degrees of freedom are suited to achieve continuity of the normal stresses. What makes the element distinctive is that its dimension is the smallest required for enforcing a weak symmetry condition on the approximate stress. This is achieved using certain “bubble matrices”, which are special divergence-free matrix-valued polynomials. We prove that the approximation error is of order $k+1$ in both the displacement and the stress, and that a postprocessed displacement approximation converging at order $k+2$ can be computed element by element. We also show that the globally coupled degrees of freedom can be reduced by hybridization to those of a displacement approximation on the element boundaries.

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