Strong and Auxiliary Forms of the Semi-Lagrangian Method for Incompressible Flows

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

In this paper we consider some particular aspects related to the semi-implicit version of a fractional step ®nite element method for compressible ¯ows that we have developed recently. The ®rst is the imposition of boundary conditions. We show that no boundary conditions at all need to be imposed in

A semi-implicit, semi-lagrangian algorithm suitable for the simulation of the dry, adiabatic, nonhydrostatic atmospheric dynamics is introduced and analysed. Height is used as vertical coordinate, without the customary terrain following normalization, thus resulting in a stable, robust, and efficien

A spectral method is proposed for the vorticity-stream function equations of the incompressible fluid flows. It is effective to overcome the lack of vorticity boundary condition. This method decouples the vorticity and stream function. At each time step, first, the vorticity is explicitly solved and