An algorithm using the finite volume element method and its splitting extrapolation

An efficient algorithm for implementing the finite-element ( ) time-domain FETD method on parallel computers is presented. An unconditionally stable implicit FETD algorithm is combined with the ( ) finite-element tearing and interconnecting FETI method. This domain decomposition algorithm con¨erges

## Abstract An overview of the extended/generalized finite element method (GEFM/XFEM) with emphasis on methodological issues is presented. This method enables the accurate approximation of solutions that involve jumps, kinks, singularities, and other locally non‐smooth features within elements. Thi

plains why it is expedient to use two distinct and dual discretization grids, it shows how they must be staggered In this paper we apply the ideas of algebraic topology to the analysis of the finite volume and finite element methods, illuminat-to achieve optimal performance and proposes a technique

The generalized ÿnite element method (GFEM) was introduced in Reference [1] as a combination of the standard FEM and the partition of unity method. The standard mapped polynomial ÿnite element spaces are augmented by adding special functions which re ect the known information about the boundary valu

Potential problems can be solved by analytical methods. However, for three-dimensional structures of geometrically complex shape with non-linear boundary conditions, numerical methods have to be applied. The most popular technique is the finite element method, which is used throughout the engineerin