CFD-Based HPCMP Systems Assessment Using AERO, AVUS, and OVERFLOW-2

Authors:
Samuel B. Cable;Thomas C. Oppe;William A. Jr. Ward;Raymond E. Gordnier;Victor S. Burnley;Matthew J. Grismer;Roy L. Jr. Campbell;Pieter G. Burning
Affiliations:
USACE Engineer Research and Development Center (ERDC), Computational Science and Engineering Group, Vicksburg, MS;USACE Engineer Research and Development Center (ERDC), Computational Science and Engineering Group, Vicksburg, MS;USACE Engineer Research and Development Center (ERDC), Computational Science and Engineering Group, Vicksburg, MS;US Air Force Research Laboratory,(AFRL),Wright-Patterson AFB, OH;US Air Force Research Laboratory,(AFRL),Wright-Patterson AFB, OH;US Air Force Research Laboratory,(AFRL),Wright-Patterson AFB, OH;US Army Research Laboratory (ARL), Aberdeen Proving Ground, MD;NASA Langley Research Center Hampton, VA
Venue:
DOD_UGC '05 Proceedings of the 2005 Users Group Conference on 2005 Users Group Conference
Year:
2005

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High-Performance Computing Acquisitions Based on the Factors that Matter

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Sustained systems performance monitoring at the U. S. Department of Defense high performance computing modernization program

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Abstract

We use Newton equations of motion and Universal Force Field to simulate large systems containing altitudinal and azimuthal molecular rotors. Gas flow, water flow, electric fields and light absorption are used to drive the rotors. These devices might ...