Efficient solution of a wave equation with fractional-order dissipative terms

H. Haddar; J. R. Li; D. Matignon

doi:10.1016/j.cam.2009.08.051

Efficient solution of a wave equation with fractional-order dissipative terms

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Abstract

We consider a wave equation with fractional-order dissipative terms modeling visco-thermal losses on the lateral walls of a duct, namely the WebsterLokshin model. Diffusive representations of fractional derivatives are used, first to prove existence and uniqueness results, then to design a numerical scheme which avoids the storage of the entire history of past data. Two schemes are proposed depending on the choice of a quadrature rule in the Laplace domain. The first one mimics the continuous energy balance but suffers from a loss of accuracy in long time simulation. The second one provides uniform control of the accuracy. However, even though the latter is more efficient and numerically stable under the standard CFL condition, no discrete energy balance has been yet found for it. Numerical results of comparisons with a closed-form solution are provided.

Original language	English
Pages (from-to)	2003-2010
Number of pages	8
Journal	Journal of Computational and Applied Mathematics
Volume	234
Issue number	6
DOIs	https://doi.org/10.1016/j.cam.2009.08.051
Publication status	Published - 15 Aug 2010

Keywords

Diffusive representation
Fractional derivative
Spectral approximation

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10.1016/j.cam.2009.08.051

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title = "Efficient solution of a wave equation with fractional-order dissipative terms",

abstract = "We consider a wave equation with fractional-order dissipative terms modeling visco-thermal losses on the lateral walls of a duct, namely the WebsterLokshin model. Diffusive representations of fractional derivatives are used, first to prove existence and uniqueness results, then to design a numerical scheme which avoids the storage of the entire history of past data. Two schemes are proposed depending on the choice of a quadrature rule in the Laplace domain. The first one mimics the continuous energy balance but suffers from a loss of accuracy in long time simulation. The second one provides uniform control of the accuracy. However, even though the latter is more efficient and numerically stable under the standard CFL condition, no discrete energy balance has been yet found for it. Numerical results of comparisons with a closed-form solution are provided.",

keywords = "Diffusive representation, Fractional derivative, Spectral approximation",

author = "H. Haddar and Li, \{J. R.\} and D. Matignon",

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T1 - Efficient solution of a wave equation with fractional-order dissipative terms

AU - Haddar, H.

AU - Li, J. R.

AU - Matignon, D.

PY - 2010/8/15

Y1 - 2010/8/15

N2 - We consider a wave equation with fractional-order dissipative terms modeling visco-thermal losses on the lateral walls of a duct, namely the WebsterLokshin model. Diffusive representations of fractional derivatives are used, first to prove existence and uniqueness results, then to design a numerical scheme which avoids the storage of the entire history of past data. Two schemes are proposed depending on the choice of a quadrature rule in the Laplace domain. The first one mimics the continuous energy balance but suffers from a loss of accuracy in long time simulation. The second one provides uniform control of the accuracy. However, even though the latter is more efficient and numerically stable under the standard CFL condition, no discrete energy balance has been yet found for it. Numerical results of comparisons with a closed-form solution are provided.

AB - We consider a wave equation with fractional-order dissipative terms modeling visco-thermal losses on the lateral walls of a duct, namely the WebsterLokshin model. Diffusive representations of fractional derivatives are used, first to prove existence and uniqueness results, then to design a numerical scheme which avoids the storage of the entire history of past data. Two schemes are proposed depending on the choice of a quadrature rule in the Laplace domain. The first one mimics the continuous energy balance but suffers from a loss of accuracy in long time simulation. The second one provides uniform control of the accuracy. However, even though the latter is more efficient and numerically stable under the standard CFL condition, no discrete energy balance has been yet found for it. Numerical results of comparisons with a closed-form solution are provided.

KW - Diffusive representation

KW - Fractional derivative

KW - Spectral approximation

U2 - 10.1016/j.cam.2009.08.051

DO - 10.1016/j.cam.2009.08.051

M3 - Article

AN - SCOPUS:77955228327

SN - 0377-0427

VL - 234

SP - 2003

EP - 2010

JO - Journal of Computational and Applied Mathematics

JF - Journal of Computational and Applied Mathematics

IS - 6

ER -

Efficient solution of a wave equation with fractional-order dissipative terms

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Keywords

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