We present a simple error estimation and mesh adaptation approach for 3D linear elastic crack propagation simulations using the eXtended Finite Element Method (X-FEM). A global extended recovery technique (Duflot and Bordas, 2008) is used to quantify the interpolation error. Based on this error distribution, four strategies relying on two different mesh optimality criteria are compared. The first aims at homogenizing the error distribution. The second minimizes the total number of elements given a target global error level. We study the behaviour of these criteria in the context of cracks treated by an X-FE approach. In particular, we investigate the convergence rates at the element-level depending its enrichment type. We conclude on the mo...
This paper introduces a recovery-type error estimator yielding upper bounds of the error in energy n...
International audienceThis paper is devoted to the numerical simulation of the dynamic propagation o...
This paper deals with the adaptive finite element analysis of structural failure. A gradient-enhance...
We present a simple error estimation and mesh adaptation approach for 3D linear elastic crack propag...
The extended finite element method (XFEM) has recently emerged as a highly efficient numerical metho...
While the regular Finite Element Method (FEM) is well developed and robust, it is not particularly w...
peer reviewedGoal oriented error estimation and adaptive procedures are essential for the accurate ...
This contribution presents an extended global derivative recovery for enriched finite element method...
A new stress recovery procedure that provides accurate estimations of the discretization error for l...
A variation of the extended finite element method for 3D fracture mechanics is proposed. It utilizes...
A variant of the extended finite element method is presented which facilitates the use of enriched e...
International audienceThe eXtended Finite Element Method (XFEM) has been used in Cast3m tosimulate ...
An extended finite element method (XFEM) for three dimensional (3D) non-planar linear elastic fractu...
This paper introduces a recovery-type error estimator yielding upper bounds of the error in energy n...
International audienceThis paper is devoted to the numerical simulation of the dynamic propagation o...
This paper deals with the adaptive finite element analysis of structural failure. A gradient-enhance...
We present a simple error estimation and mesh adaptation approach for 3D linear elastic crack propag...
The extended finite element method (XFEM) has recently emerged as a highly efficient numerical metho...
While the regular Finite Element Method (FEM) is well developed and robust, it is not particularly w...
peer reviewedGoal oriented error estimation and adaptive procedures are essential for the accurate ...
This contribution presents an extended global derivative recovery for enriched finite element method...
A new stress recovery procedure that provides accurate estimations of the discretization error for l...
A variation of the extended finite element method for 3D fracture mechanics is proposed. It utilizes...
A variant of the extended finite element method is presented which facilitates the use of enriched e...
International audienceThe eXtended Finite Element Method (XFEM) has been used in Cast3m tosimulate ...
An extended finite element method (XFEM) for three dimensional (3D) non-planar linear elastic fractu...
This paper introduces a recovery-type error estimator yielding upper bounds of the error in energy n...
International audienceThis paper is devoted to the numerical simulation of the dynamic propagation o...
This paper deals with the adaptive finite element analysis of structural failure. A gradient-enhance...