The evaluation of non-reflecting boundary conditions for duct acoustic computation

Non-reflecting boundary conditions are introduced for the two-dimensional Fresnel/Schrödinger equation. These are nonlocal in time and in space. Time discretization is done by the trapezoidal rule in the interior and by convolution quadrature on the boundary. A convergence estimate is given for the

A modiÿed version of an exact Non-re ecting Boundary Condition (NRBC) ÿrst derived by Grote and Keller is implemented in a ÿnite element formulation for the scalar wave equation. The NRBC annihilate the ÿrst N wave harmonics on a spherical truncation boundary, and may be viewed as an extension of th

When solving the wave equation in in®nite regions using ®nite element methods, the domain must be truncated. We investigate the accuracy of time-dependent non-re¯ecting boundary conditions (NRBC) derived in Grote, Keller (1995), when implemented in the ®nite element method. The NRBC annihilate the ®

The main difficulty in finding the solution of the diffusion equation in the human lung lies in the extreme complexity of the boundary conditions. Furthermore, the role played by the alveolar walls has never been studied before. We have constructed, from anatomical data, the boundary conditions and

A set of non-homogeneous radiation and outflow boundary conditions which automatically generate prescribed incoming acoustic or vorticity waves and, at the same time, are almost transparent to outgoing sound waves produced internally in a finite computation domain is proposed. This type of boundary