Journal ArticleDOI
Element‐free Galerkin methods
Ted Belytschko,Y. Y. Lu,L. Gu +2 more
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In this article, an element-free Galerkin method which is applicable to arbitrary shapes but requires only nodal data is applied to elasticity and heat conduction problems, where moving least-squares interpolants are used to construct the trial and test functions for the variational principle.Abstract:
An element-free Galerkin method which is applicable to arbitrary shapes but requires only nodal data is applied to elasticity and heat conduction problems. In this method, moving least-squares interpolants are used to construct the trial and test functions for the variational principle (weak form); the dependent variable and its gradient are continuous in the entire domain. In contrast to an earlier formulation by Nayroles and coworkers, certain key differences are introduced in the implementation to increase its accuracy. The numerical examples in this paper show that with these modifications, the method does not exhibit any volumetric locking, the rate of convergence can exceed that of finite elements significantly and a high resolution of localized steep gradients can be achieved. The moving least-squares interpolants and the choices of the weight function are also discussed in this paper.read more
Citations
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A simple error estimator for extended finite elements
TL;DR: In this article, the authors presented the idea of an a posteriori error estimate for enriched (extended) finite elements (XFEM) using extended moving least squares smoothing constructed using the diffraction method to preserve the discontinuity.
BookDOI
Computational Multiscale Modeling of Fluids and Solids
TL;DR: In this paper, the authors provide a sound mathematical background of many abstract concepts prevalently used in physical theories, such as tensors and manifolds, which are important mathematical tools for a succinct and precise formulation of physical theories.
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Boundary knot method for 2D and 3D Helmholtz and convection-diffusion problems under complicated geometry
TL;DR: The boundary knot method (BKM) of very recent origin is an inherently meshless, integration-free, boundary-type, radial basis function collocation technique for the numerical discretization of general partial differential equation systems.
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Discrete simulation of granular and particle-fluid flows: from fundamental study to engineering application
TL;DR: This review discusses the enabling methods and technologies for multiscale discrete simulations (MSDS), and concludes that with these developments, MSDS could soon become, among others, a mainstream simulation approach in chemical engineering which enables VPE.
Journal ArticleDOI
Mesh-free simulations of shear banding in large deformation
Shaofan Li,Wei Hao,Wing Kam Liu +2 more
TL;DR: It is demonstrated in the paper that mesh-free interpolants can accurately capture finite shear deformation under large mesh distortion without recourse to special mesh design and remeshing in numerical simulations.
References
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Smoothed particle hydrodynamics: Theory and application to non-spherical stars
R. A. Gingold,Joseph J Monaghan +1 more
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Theory of Elasticity (3rd ed.)
Journal ArticleDOI
Surfaces generated by moving least squares methods
Peter Lancaster,K. Salkauskas +1 more
TL;DR: In this article, an analysis of moving least squares (m.l.s.) methods for smoothing and interpolating scattered data is presented, in particular theorems concerning the smoothness of interpolants and the description of m. l.s. processes as projection methods.
Journal ArticleDOI
Generalizing the finite element method: Diffuse approximation and diffuse elements
TL;DR: The diffuse element method (DEM) as discussed by the authors is a generalization of the finite element approximation (FEM) method, which is used for generating smooth approximations of functions known at given sets of points and for accurately estimating their derivatives.
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