Efficient computation of the Green's function and its derivatives for three-dimensional anisotropic elasticity in BEM analysis

An alternative scheme to compute the Green's function and its derivatives for three dimensional generally anisotropic elastic solids is presented in this paper. These items are essential in the formulation of the boundary element method (BEM); their evaluation has remained a subject of interest...

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Veröffentlicht in:	Engineering analysis with boundary elements 2012-12, Vol.36 (12), p.1746-1755
Hauptverfasser:	Shiah, Y.C., Tan, C.L., Wang, C.Y.
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Sprache:	eng
Schlagworte:	Algebra Anisotropic elasticity Anisotropy Boundary element method Computational efficiency Derivatives Exact sciences and technology Fourier series Fundamental areas of phenomenology (including applications) Fundamental solution Green's function Green's functions Mathematical analysis Mathematical models Mathematics Number theory Physics Sciences and techniques of general use Solid mechanics Static elasticity (thermoelasticity...) Stroh's eigenvalues Structural and continuum mechanics
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container_title	Engineering analysis with boundary elements
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creator	Shiah, Y.C. Tan, C.L. Wang, C.Y.
description	An alternative scheme to compute the Green's function and its derivatives for three dimensional generally anisotropic elastic solids is presented in this paper. These items are essential in the formulation of the boundary element method (BEM); their evaluation has remained a subject of interest because of the mathematical complexity. The Green's function considered here is the one introduced by Ting and Lee [Q. J. Mech. Appl. Math. 1997; 50: 407–26] which is of real-variable, explicit form expressed in terms of Stroh's eigenvalues. It has received attention in BEM only quite recently. By taking advantage of the periodic nature of the spherical angles when it is expressed in the spherical coordinate system, it is proposed that this Green's function be represented by a double Fourier series. The Fourier coefficients are determined numerically only once for a given anisotropic material; this is independent of the number of field points in the BEM analysis. Derivatives of the Green's function can be performed by direct spatial differentiation of the Fourier series. The resulting formulations are more concise and simpler than those derived analytically in closed form in previous studies. Numerical examples are presented to demonstrate the veracity and superior efficiency of the scheme, particularly when the number of field points is very large, as is typically the case when analyzing practical three dimensional engineering problems.
doi_str_mv	10.1016/j.enganabound.2012.05.008
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These items are essential in the formulation of the boundary element method (BEM); their evaluation has remained a subject of interest because of the mathematical complexity. The Green's function considered here is the one introduced by Ting and Lee [Q. J. Mech. Appl. Math. 1997; 50: 407–26] which is of real-variable, explicit form expressed in terms of Stroh's eigenvalues. It has received attention in BEM only quite recently. By taking advantage of the periodic nature of the spherical angles when it is expressed in the spherical coordinate system, it is proposed that this Green's function be represented by a double Fourier series. The Fourier coefficients are determined numerically only once for a given anisotropic material; this is independent of the number of field points in the BEM analysis. Derivatives of the Green's function can be performed by direct spatial differentiation of the Fourier series. 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These items are essential in the formulation of the boundary element method (BEM); their evaluation has remained a subject of interest because of the mathematical complexity. The Green's function considered here is the one introduced by Ting and Lee [Q. J. Mech. Appl. Math. 1997; 50: 407–26] which is of real-variable, explicit form expressed in terms of Stroh's eigenvalues. It has received attention in BEM only quite recently. By taking advantage of the periodic nature of the spherical angles when it is expressed in the spherical coordinate system, it is proposed that this Green's function be represented by a double Fourier series. The Fourier coefficients are determined numerically only once for a given anisotropic material; this is independent of the number of field points in the BEM analysis. Derivatives of the Green's function can be performed by direct spatial differentiation of the Fourier series. 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subjects	Algebra Anisotropic elasticity Anisotropy Boundary element method Computational efficiency Derivatives Exact sciences and technology Fourier series Fundamental areas of phenomenology (including applications) Fundamental solution Green's function Green's functions Mathematical analysis Mathematical models Mathematics Number theory Physics Sciences and techniques of general use Solid mechanics Static elasticity (thermoelasticity...) Stroh's eigenvalues Structural and continuum mechanics
title	Efficient computation of the Green's function and its derivatives for three-dimensional anisotropic elasticity in BEM analysis
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