Title of article
THE BOUNDARY NODE METHOD FOR POTENTIAL PROBLEMS
Author/Authors
YU XIE MUKHERJEE، نويسنده , , SUBRATA MUKHERJEE، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 1997
Pages
19
From page
797
To page
815
Abstract
The Element-Free Galerkin (EFG) method allows one to use a nodal data structure (usually with an
underlying cell structure) within the domain of a body of arbitrary shape. The usual EFG combines Moving
Least-Squares (MLS) interpolants with a variational principle (weak form) and has been used to solve
two-dimensional (2-D) boundary value problems in mechanics such as in potential theory, elasticity and
fracture. This paper proposes a combination of MLS interpolants with Boundary Integral Equations (BIE)
in order to retain both the meshless attribute of the former and the dimensionality advantage of the latter!
This new method, called the Boundary Node Method (BNM), only requires a nodal data structure on the
bounding surface of a body whose dimension is one less than that of the domain itself. An underlying cell
structure is again used for numerical integration. In principle, the BNM, for 3-D problems, should be
extremely powerful since one would only need to put nodes (points) on the surface of a solid model for an
object.
Numerical results are presented in this paper for the solution of LaplaceÕs equation in 2-D. Dirichlet,
Neumann and mixed problems have been solved, some on bodies with piecewise straight and others with
curved boundaries. Results from these numerical examples are extremely encouraging.
Keywords
Element-free Galerkin method , MESHLESS , Boundary node method
Journal title
International Journal for Numerical Methods in Engineering
Serial Year
1997
Journal title
International Journal for Numerical Methods in Engineering
Record number
423288
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