Full discretisation of second-order nonlinear evolution equations: Strong convergence and applications

Etienne Emmrich; David Šiška

doi:10.2478/cmam-2011-0025

Full discretisation of second-order nonlinear evolution equations: Strong convergence and applications

Etienne Emmrich^*, David Šiška

^*Corresponding author for this work

School of Mathematics

Research output: Contribution to journal › Article › peer-review

Abstract

Recent results on convergence of fully discrete approximations combining the Galerkin method with the explicit-implicit Euler scheme are extended to strong convergence under additional monotonicity assumptions. It is shown that these abstract results, formulated in the setting of evolution equations, apply, for example, to the partial differential equation for vibrating membrane with nonlinear damping and to another partial differential equation that is similar to one of the equations used to describe martensitic transformations in shape-memory alloys. Numerical experiments are performed for the vibrating membrane equation with nonlinear damping which support the convergence results.

Original language	English
Pages (from-to)	441-459
Number of pages	19
Journal	Computational Methods in Applied Mathematics
Volume	11
Issue number	4
DOIs	https://doi.org/10.2478/cmam-2011-0025
Publication status	Published - 1 Jan 2011

Keywords / Materials (for Non-textual outputs)

Convergence
Evolution equation of second order
Galerkin method
Shape-memory alloys
Time discretisation
Vibrating membrane

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10.2478/cmam-2011-0025

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title = "Full discretisation of second-order nonlinear evolution equations: Strong convergence and applications",

abstract = "Recent results on convergence of fully discrete approximations combining the Galerkin method with the explicit-implicit Euler scheme are extended to strong convergence under additional monotonicity assumptions. It is shown that these abstract results, formulated in the setting of evolution equations, apply, for example, to the partial differential equation for vibrating membrane with nonlinear damping and to another partial differential equation that is similar to one of the equations used to describe martensitic transformations in shape-memory alloys. Numerical experiments are performed for the vibrating membrane equation with nonlinear damping which support the convergence results.",

keywords = "Convergence, Evolution equation of second order, Galerkin method, Shape-memory alloys, Time discretisation, Vibrating membrane",

author = "Etienne Emmrich and David {\v S}i{\v s}ka",

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doi = "10.2478/cmam-2011-0025",

language = "English",

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T2 - Strong convergence and applications

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AU - Šiška, David

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N2 - Recent results on convergence of fully discrete approximations combining the Galerkin method with the explicit-implicit Euler scheme are extended to strong convergence under additional monotonicity assumptions. It is shown that these abstract results, formulated in the setting of evolution equations, apply, for example, to the partial differential equation for vibrating membrane with nonlinear damping and to another partial differential equation that is similar to one of the equations used to describe martensitic transformations in shape-memory alloys. Numerical experiments are performed for the vibrating membrane equation with nonlinear damping which support the convergence results.

AB - Recent results on convergence of fully discrete approximations combining the Galerkin method with the explicit-implicit Euler scheme are extended to strong convergence under additional monotonicity assumptions. It is shown that these abstract results, formulated in the setting of evolution equations, apply, for example, to the partial differential equation for vibrating membrane with nonlinear damping and to another partial differential equation that is similar to one of the equations used to describe martensitic transformations in shape-memory alloys. Numerical experiments are performed for the vibrating membrane equation with nonlinear damping which support the convergence results.

KW - Convergence

KW - Evolution equation of second order

KW - Galerkin method

KW - Shape-memory alloys

KW - Time discretisation

KW - Vibrating membrane

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JO - Computational Methods in Applied Mathematics

JF - Computational Methods in Applied Mathematics

IS - 4

ER -

Full discretisation of second-order nonlinear evolution equations: Strong convergence and applications

Abstract

Keywords / Materials (for Non-textual outputs)

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