This paper presents a method of interpolation and regularisation of finite element (FE) results based on radial basis functions (RBF) capable to upscale at a finer resolution the displacement fields and, accordingly, the strains and the stresses obtained with a coarse mesh. RBF interpolation of nodal displacements supplies an analytical approximation of the field over the whole discretized domain, suitable for mathematical differentiation. The stress status can be retrieved starting from the given analytical expression of the strain. The introduced technique is tested on two-dimensional FE problems presenting stress raisers: a plate in traction with a central hole, a plate in traction with nine aligned holes and a compressed wing rib with t...
Radial basis functions (RBFs) based mesh morphing allows to adapt the shape of a computational grid ...
A finite element formulation, based on assumed stress functions, is developed for the linear elastic...
Strong-form meshless methods received much attention in recent years and are being extensively resea...
This paper presents a method of interpolation and regularisation of finite element (FE) results base...
This paper presents a method able to upscale finite element (FE) results obtained for coarse meshes ...
In this paper a method to improve the stress state on a 2D finite element (FE) Q1 coarse mesh for fr...
Shape functions provide the deformation field inside a finite element from the nodal displacements: ...
The recovery of the stress gradient in finite elements problems is a widely discussed topic with man...
Abstract The three-dimensional Theory of Elasticity equations lead to a complex solution for most pr...
Error estimation and adaptive applications help to control the discretization errors in finite eleme...
In this article, an enriched radial point interpolation method (e-RPIM) is developed for computation...
Radial basis functions (RBFs) based mesh morphing allows to adapt the shape of a computational grid ...
A finite element formulation, based on assumed stress functions, is developed for the linear elastic...
Strong-form meshless methods received much attention in recent years and are being extensively resea...
This paper presents a method of interpolation and regularisation of finite element (FE) results base...
This paper presents a method able to upscale finite element (FE) results obtained for coarse meshes ...
In this paper a method to improve the stress state on a 2D finite element (FE) Q1 coarse mesh for fr...
Shape functions provide the deformation field inside a finite element from the nodal displacements: ...
The recovery of the stress gradient in finite elements problems is a widely discussed topic with man...
Abstract The three-dimensional Theory of Elasticity equations lead to a complex solution for most pr...
Error estimation and adaptive applications help to control the discretization errors in finite eleme...
In this article, an enriched radial point interpolation method (e-RPIM) is developed for computation...
Radial basis functions (RBFs) based mesh morphing allows to adapt the shape of a computational grid ...
A finite element formulation, based on assumed stress functions, is developed for the linear elastic...
Strong-form meshless methods received much attention in recent years and are being extensively resea...