Euler calculations with embedded Cartesian grids and small-perturbation boundary conditions

Euler calculations with embedded Cartesian grids and small-perturbation boundary conditions

This study examines the use of stationary Cartesian mesh for steady and unsteady flow computations. The surface boundary conditions are imposed by reflected points. A cloud of nodes in the vicinity of the surface is used to get a weighted average of the flow properties via a gridless least-squares t...

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Veröffentlicht in:Journal of computational physics 2010-05, Vol.229 (9), p.3523-3542
Hauptverfasser: Liao, W., Koh, E.P.C., Tsai, H.M., Liu, F.
Format: Artikel
Sprache:eng
Schlagworte:
Boundary conditions
Cartesian
Cartesian grid
Computation
Computational efficiency
Computational techniques
Displacement
Embedded multigrid
Exact sciences and technology
Least squares method
Least-squares approximation
Mathematical analysis
Mathematical methods in physics
Physics
Small-perturbation method
Surface boundary
Unsteady flow
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Beschreibung
Zusammenfassung:This study examines the use of stationary Cartesian mesh for steady and unsteady flow computations. The surface boundary conditions are imposed by reflected points. A cloud of nodes in the vicinity of the surface is used to get a weighted average of the flow properties via a gridless least-squares technique. If the displacement of the moving surface from the original position is typically small, a small-perturbation boundary condition method can be used. To ensure computational efficiency, multigrid solution is made via a framework of embedded grids for local grid refinement. Computations of airfoil wing and wing-body test cases show the practical usefulness of the embedded Cartesian grids with the small-perturbation boundary conditions approach.
ISSN:0021-9991
1090-2716
DOI:10.1016/j.jcp.2010.01.014