Dispersion properties of simple 3D finite elements

A method is presented for the numerical computation of the wavenumbers and associated modes of the cross-section of thin-walled waveguides. The method is based on finite element techniques. A thin-shell type finite element of the cross-section is developed by using the virtual work formulation for o

Several new elements are compared to the standard trilinear velocity+onstant pressure element ( Q , -P,,) for the solution of the three-dimensional Navier-Stokes equations by the finite element method. The test problem is the cubic wall-driven cavity with solution sought at Reynolds number of 400 a

## Abstract Objective of this work is the numerical solution of chemically reacting flows in three dimensions described by detailed reaction mechanism. The contemplated problems include, e.g. burners with 3D geometry. Contrary to the usual operator splitting method the equations are treated fully c

less than 0.35 dB and a return loss of better than 15 dB was achieved from 1 to 16 GHz. As the exact values of the permittivities of the materials we used are not known, the simulations were performed with the values of 4 for the glass permittivity [8], and 11.6 and 4000⍀ cm for the silicon permitt

The finite element method (FEM) with local absorbing boundary conditions has been recently applied to compute electromagnetic scattering from large 3-D geometries. In this paper, we present details pertaining to code implementation and optimization. Various types of sparse matrix storage schemes are