Parallel iterative methods for Navier–Stokes equations and application to eigenvalue computation

We present a specific use of domain decomposition and decomposition in function space combined with asymptotic analytical qualitative results to obtain, on parallel computers, efficient and accurate solvers [3] for rapidly varying quasi-planar unsteady combustion fronts in liquids. In particular, we

A novel Navier-Stokes solver based on the boundary integral equation method is presented. The solver can be used to obtain flow solutions in arbitrary 2D geometries with modest computational effort. The vorticity transport equation is modelled as a modified Helmholtz equation with the wave number de

The performance of three iterative methods, local SOR, preconditioned generalized conjugate gradient methods such as ORTHOMIN( 1) and the GCG-LS method with preconditioning matrices derived by incomplete (modified and unmodified) pointwise factorizations of the matrix corresponding to implicit finit

The present paper consists of two parts. In part 1, a new technique of treating Neumann boundary conditions with an explicit Chebyshev collocation method is developed. Any Neumann boundary condition can be satisfied by adjusting all the Chebyshev coefficients of a solution, which results in a small

An improved projection scheme is proposed and applied to pseudospectral collocation-Chebyshev approximation for the incompressible Navier-Stokes equations. It consists of introducing a correct predictor for the pressure, one which is consistent with a divergence-free velocity field at each time step