Parallel finite element computation of missile aerodynamics

A parallel semi-explicit iterative ®nite element computational procedure for modelling unsteady incompressible ¯uid ¯ows is presented. During the procedure, element ¯ux vectors are calculated in parallel and then assembled into global ¯ux vectors. Equilibrium iterations which introduce some `local i

Recent efforts to develop and apply adaptive finite element techniques for solving complex flow problems are reviewed. The emphasis is not on new methods but on how to use existing methods to achieve accurate predictions. Various sources of errors, and means of detecting them, are discussed. The aim

We refer to as mixed element/volume (MEV) methods the application of ®nite element for diffusion terms and ®nite volume for advection terms in a ¯ow model. The compatibility of these methods can be checked for some low-order approximations; the resulting schemes may enjoy the relative mesh-regularit

In the near future, large ram-air parachutes are expected to provide the capability of delivering 21 ton payloads from altitudes as high as 25,000 ft. In development and test and evaluation of these parachutes the size of the parachute needed and the deployment stages involved make high-performance

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

We address here some computational aspects of the natural-mode ®nite element method (NM-FEM), a technique recently developed by the authors for the analysis of arbitrary composite shells. We consider in particular a model problem comprising a 45a À 45a0a90 S cylindrical composite shell with 2398 deg