An Implicit Multigrid Method for Turbulent Combustion

The application of multigrid methods is complicated if the set of governing equations contains strongly nonlinear source terms. This is the case for finite-rate chemistry as well as for turbulence conservation equations. In most cases strong nonlinearities within the chemical production rates preven

are needed before solutions of large-scale chemically reacting, viscous flowfields can be considered routine enough to be used An implicit algorithm for computing viscous flows in chemical nonequilibrium is presented. Emphasis is placed on the numerical in other than a research environment. efficie

A multigrid method for computing steady solutions of the compressible Navier-Stokes equations is described. The convection part of the equations is approximated by a simple low-order upwind-biased scheme employed for multigrid relaxation in combination with a higher order essentially non-oscillatory

The development of new aeronautic projects require accurate and ef®cient simulations of compressible ¯ows in complex geometries. It is well known that most ¯ows of interest are at least locally turbulent and that the modelling of this turbulence is critical for the reliability of the computations. A

In the computational simulation of uid ow and scalar transport, multigrid iterative solution techniques often fail or stall when the discrete linearized equations have strongly anisotropic coe cients. In the present work, an adaptive agglomeration algorithm for forming coarse grids is presented that

A multigrid semi-implicit ®nite difference method is presented to solve the two-dimensional shallow water equations which describe the behaviour of basin water under the in¯uence of the Coriolis force, atmospheric pressure gradients and tides. The semi-implicit ®nite difference method discretizes im