An implicit Lagrangian lattice Boltzmann method for the compressible flows

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

This paper compares in detail the lattice Boltzmann method and an isothermal Navier-Stokes method. It is found that these two methods are closely related to each other. Both methods satisfy similar macroscopic governing equations in their continuous forms, but they differ from each other in their di

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

Classical semi-implicit backward Euler/Adams-Bashforth time discretizations of the Navier-Stokes equations induce, for high-Reynolds number flows, severe restrictions on the time step. Such restrictions can be relaxed by using semi-Lagrangian schemes essentially based on splitting the full problem i