Nonlinear artificial boundary conditions for the Navier-Stokes equations in an aperture domain

The compressible Navier-Stokes equations belong to the class of incompletely parabolic systems. The general method developed by Laurence Halpern for deriving artificial boundary conditions for incompletely parabolic perturbations of hyperbolic systems is applied to the linearized compressible Navier

In this paper we investigate new boundary conditions for the incompressible, timèe-dependent Navier-Stokes equation. Especially inflow and outflow conditions are considered. The equations are linearized around a constant flow, so that we can use Laplace-Fourier technique to investigate the strength

In the first part of this paper (J. Comput. Phys. 137, 1, 1997), continuous artificial boundary conditions for the linearized compressible Navier-Stokes equations were proposed which were valid for small viscosities, high time frequencies, and long space wavelengths. In the present work, a new hiera

The barotropic compressible Navier᎐Stokes equations in an unbounded domain Ž . Ž . are studied. We prove the unique existence of the solution u, p of the system 1.1 in the Sobolev space H kq 3 = H kq 2 provided that the derivatives of the data of the problem are sufficiently small, where k G 0 is an

## Abstract On a three–dimensional exterior domain Ω we consider the Dirichlet problem for the stationary Navier–Stokes system. We construct an approximation problem on the domain Ω~__R__~, which is the intersection of Ω with a sufficiently large ball, while we create nonlinear, but local artificia