Reversed stability conditions in transient finite element analysis (Q1104804)
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scientific article; zbMATH DE number 4057140
| Language | Label | Description | Also known as |
|---|---|---|---|
| English | Reversed stability conditions in transient finite element analysis |
scientific article; zbMATH DE number 4057140 |
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Reversed stability conditions in transient finite element analysis (English)
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1988
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Numerical methods which introduce artificially unstable modes are discussed. In structural and elastodynamics these result from optimal mass lumping with higher-order elements. In fluid mechanics an additional source of these modes can be a penalty function with alternating signs. These modes yield unstable modal equations; however, they do not necessarily imply unstable transient integration in the presence of algorithmic damping. Stable integration can be achieved by satisfying a stability condition in which the roles of space-step and time-step are reversed. Elatodyamics, the Navier-Stokes equations, and non-Newtonian fluids provide numerical examples.
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numerical experiment
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unstable high-frequency modes
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semidiscrete equations
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algorithmic damping
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Newmark method
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generalized trapezoidal methods
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artificially unstable modes
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elastodynamics
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optimal mass lumping
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higher-order elements
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fluid mechanics
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penalty function with alternating signs
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unstable modal equations
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Stable integration
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