Title of article
Inverse Lax-Wendroff procedure for numerical boundary conditions of conservation laws
Author/Authors
Tan، نويسنده , , Sirui and Shu، نويسنده , , Chi-Wang، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2010
Pages
23
From page
8144
To page
8166
Abstract
We develop a high order finite difference numerical boundary condition for solving hyperbolic conservation laws on a Cartesian mesh. The challenge results from the wide stencil of the interior high order scheme and the fact that the boundary intersects the grids in an arbitrary fashion. Our method is based on an inverse Lax-Wendroff procedure for the inflow boundary conditions. We repeatedly use the partial differential equation to write the normal derivatives to the inflow boundary in terms of the time derivatives and the tangential derivatives. With these normal derivatives, we can then impose accurate values of ghost points near the boundary by a Taylor expansion. At outflow boundaries, we use Lagrange extrapolation or least squares extrapolation if the solution is smooth, or a weighted essentially non-oscillatory (WENO) type extrapolation if a shock is close to the boundary. Extensive numerical examples are provided to illustrate that our method is high order accurate and has good performance when applied to one and two-dimensional scalar or system cases with the physical boundary not aligned with the grids and with various boundary conditions including the solid wall boundary condition. Additional numerical cost due to our boundary treatment is discussed in some of the examples.
Keywords
hyperbolic conservation laws , Numerical boundary conditions , Finite difference method , Cartesian mesh , Lax-Wendroff procedure , Extrapolation , Solid wall
Journal title
Journal of Computational Physics
Serial Year
2010
Journal title
Journal of Computational Physics
Record number
1482890
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