Title :
Tera-scalable Fourier Spectral Element Code for DNS of Channel Turbulent Flow at High Reynolds Number
Author_Institution :
Div. of Phys., Argonne Nat. Lab., IL
Abstract :
Due to the extensive requirement of memory and speed for direct numerical simulation (DNS) of channel turbulence, people can only perform DNS at moderate Reynolds number before. With the fast development of supercomputers, it has become more and more approachable for researchers to perform DNS of turbulence at high Reynolds number. This makes it imperative to consider the development of tera-scalable DNS codes that are capable of fully exploiting these massively parallel machines. In order to achieve this, three parallel models (ID, 2D and 3D domain decompositions) have been implemented and bench-marked. All these models have been successfully ported on BlueGene/L. We have benchmarked these models on BG/L at ANL and BGW at IBM Watson center. Details of these models have been described, discussed and presented in this paper. The optimized model can be used to perform DNS at high Reynolds number in the near future.
Keywords :
channel flow; computational fluid dynamics; fast Fourier transforms; numerical analysis; parallel machines; turbulence; channel turbulent flow; computational fluid dynamics; direct numerical simulation; high Reynolds number; parallel machines; tera-scalable Fourier spectral element code; Boundary conditions; Computational modeling; Costs; Earth; Fourier series; Laboratories; Numerical simulation; Physics; Supercomputers; USA Councils; DNS; Domain Decomposition; Fourier Spectral Element Method; high Reynolds number;
Conference_Titel :
Parallel and Distributed Processing Symposium, 2007. IPDPS 2007. IEEE International
Conference_Location :
Long Beach, CA
Print_ISBN :
1-4244-0910-1
Electronic_ISBN :
1-4244-0910-1
DOI :
10.1109/IPDPS.2007.370570
