Title :
Partitioning and dynamic load balancing of adaptive hybrid grids for large-scale turbulent flow simulations
Author :
Minyard, T. ; Kallinderis, Y. ; Schulz, K.
Author_Institution :
Dept. of Aerosp. Eng. & Eng. Mech., Texas Univ., Austin, TX, USA
Abstract :
A new partitioning method for complex 3-D hybrid prismatic/tetrahedral meshes is presented. The method uses an orthogonal recursive bisection approach on a special octree corresponding to the hybrid grid. The octree is generated automatically and handles any type of 3-D geometry and domain connectivity. It is employed for partitioning of static, as well as dynamic adaptive meshes. The method yields similar quality partitions for very divergent geometries, such as a sphere and an aircraft configuration. The strategy for load balancing is applied to octants which leads to an efficient parallel algorithm. Results include partitioning a hybrid grid around an aircraft configuration and octree-based load balancing for a dynamically adapted mesh. The method is applied to large-scale turbulent flow simulations around aircraft configurations
Keywords :
aerospace computing; aircraft; computational geometry; digital simulation; flow simulation; octrees; parallel algorithms; parallel machines; resource allocation; 3D geometry; adaptive hybrid grids; aircraft configuration; domain connectivity; dynamic adaptive meshes; dynamic load balancing; hybrid grid; hybrid prismatic tetrahedral meshes; large-scale turbulent flow simulation; octants; octree; orthogonal recursive bisection; parallel algorithm; partitioning; three dimensional geometry; Aerodynamics; Aerospace engineering; Aerospace simulation; Aircraft; Computational modeling; Computer simulation; Concurrent computing; Geometry; Large-scale systems; Load management;
Conference_Titel :
System Sciences, 1996., Proceedings of the Twenty-Ninth Hawaii International Conference on ,
Conference_Location :
Wailea, HI
Print_ISBN :
0-8186-7324-9
DOI :
10.1109/HICSS.1996.495508
