First-order system least squares (FOSLS) for spatial linear elasticity: Pure traction (Q2706372)
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scientific article
| Language | Label | Description | Also known as |
|---|---|---|---|
| English | First-order system least squares (FOSLS) for spatial linear elasticity: Pure traction |
scientific article |
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19 March 2001
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L(2) norm
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first-order system least-squares functionals
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pure traction
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three-dimensional linear elasticity
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dual norms
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product Sobolev norms
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Poisson ratio
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finite element discretization
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iterative solver
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First-order system least squares (FOSLS) for spatial linear elasticity: Pure traction (English)
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This paper develops first-order system least-squares (FOSLS) functionals for solving the pure traction problem in three-dimensional linear elasticity. It is a direct extension of an earlier paper on planar elasticity [\textit{Z. Cai}, \textit{Th. A. Manteuffel}, \textit{S. F. McCormick} and \textit{S. V. Parter}, SIAM J. Numer. Anal. 35, No. 1, 320-335 (1998; Zbl 0968.74061)]. Two functionals are constructed, one involving \(L^2\) norms of the first-order system, and the other involving dual norms. These functionals are shown to be equivalent to appropriate product Sobolev norms, uniformly in the Poisson ratio. These results imply that standard finite element discretization and iterative solver techniques can be applied to obtain an optimal performance -- even if the material is near the incompressible limit.
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