In some domains, an N-Body simulation is key to solving for the movement and forces of a dynamic system of particles. At each time step, the force that one body exacts on each other, and then the velocity can be computed. The simulation can continue up to a desired number of time steps.
Today Advanced Clustering Technologies announced that the University of Central Oklahoma’s Center for Research and Education in Interdisciplinary Computation (CREIC) has selected the company to build their next supercomputer. The 32 Teraflop HPC cluster will be named “Buddy” in honor of the university’s mascot, Buddy Bronco.
“With the advent of massively parallel computing coprocessors, numerical optimization for deep-learning disciplines is now possible. Complex real-time pattern recognition, for example, that can be used for self driving cars and augmented reality can be developed and high performance achieved with the use of specialized, highly tuned libraries. By just using the Message Passing Interface (MPI) API, very high performance can be attained on hundreds to thousands of Intel Xeon Phi processors.”
In this video, Niall Wilson describes how ICHEC delivers top-quality technology services and support to universities and enterprises. “Based on the solution’s superior price performance, ICHEC deployed Fionn, a supercomputer built on SGI ICE X hardware running SUSE Linux Enterprise Server. On implementing Fionn, ICHEC was funded by Intel to work on its new many-core technology as an official Intel Parallel Computing Center.”
Today NERSC announced that their Cori Phase 1 system will be the first supercomputer installed in the new Computational Research and Theory Facility, which is now in the final stages of construction at LBNL. Expected to be delivered this summer, the Cray XC40 supercomputer will be powered by Intel Haswell processors and Cray’s DataWarp burst buffer technology.