A numerical method for the analysis of state-changing processes in granular media

This paper describes a numerical procedure for the solution of metalworking problems of a strainhardening material. The overall metalworking process is split up into a number of stages and the governing equations for a typical stage are set up in terms of incremental displacements. The incremental d

Finite element methods are used to solve a coupled system of nonlinear partial differential equations, which models incompressible miscible displacement in porous media. Through a backward finite difference discretization in time, we define a sequentially implicit time-stepping algorithm that uncoup

The time-dependent Schrodinger equation is solved for an electron with potentials of the form fJr) + f2(r, t)U(t), where U ( t ) is the unit step function. We use a product formulation, solving for F(r, t ) where the wave function Wr, f) = F(r, t)@(r)ePiE"\* in which @(r)e-iE\*'\* is the solution fo

## Abstract A finite element code for steady‐state hot rolling processes of rigid–visco‐plastic materials under plane–strain conditions was developed in a mixed Eulerian–Lagrangian framework. This special set up allows for a direct calculation of the local deformations occurring at the free surface