21,556 research outputs found
4.45 Pflops Astrophysical N-Body Simulation on K computer -- The Gravitational Trillion-Body Problem
As an entry for the 2012 Gordon-Bell performance prize, we report performance
results of astrophysical N-body simulations of one trillion particles performed
on the full system of K computer. This is the first gravitational trillion-body
simulation in the world. We describe the scientific motivation, the numerical
algorithm, the parallelization strategy, and the performance analysis. Unlike
many previous Gordon-Bell prize winners that used the tree algorithm for
astrophysical N-body simulations, we used the hybrid TreePM method, for similar
level of accuracy in which the short-range force is calculated by the tree
algorithm, and the long-range force is solved by the particle-mesh algorithm.
We developed a highly-tuned gravity kernel for short-range forces, and a novel
communication algorithm for long-range forces. The average performance on 24576
and 82944 nodes of K computer are 1.53 and 4.45 Pflops, which correspond to 49%
and 42% of the peak speed.Comment: 10 pages, 6 figures, Proceedings of Supercomputing 2012
(http://sc12.supercomputing.org/), Gordon Bell Prize Winner. Additional
information is http://www.ccs.tsukuba.ac.jp/CCS/eng/gbp201
NASA's supercomputing experience
A brief overview of NASA's recent experience in supercomputing is presented from two perspectives: early systems development and advanced supercomputing applications. NASA's role in supercomputing systems development is illustrated by discussion of activities carried out by the Numerical Aerodynamical Simulation Program. Current capabilities in advanced technology applications are illustrated with examples in turbulence physics, aerodynamics, aerothermodynamics, chemistry, and structural mechanics. Capabilities in science applications are illustrated by examples in astrophysics and atmospheric modeling. Future directions and NASA's new High Performance Computing Program are briefly discussed
Parallel machine architecture and compiler design facilities
The objective is to provide an integrated simulation environment for studying and evaluating various issues in designing parallel systems, including machine architectures, parallelizing compiler techniques, and parallel algorithms. The status of Delta project (which objective is to provide a facility to allow rapid prototyping of parallelized compilers that can target toward different machine architectures) is summarized. Included are the surveys of the program manipulation tools developed, the environmental software supporting Delta, and the compiler research projects in which Delta has played a role
Large-scale grid-enabled lattice-Boltzmann simulations of complex fluid flow in porous media and under shear
Well designed lattice-Boltzmann codes exploit the essentially embarrassingly
parallel features of the algorithm and so can be run with considerable
efficiency on modern supercomputers. Such scalable codes permit us to simulate
the behaviour of increasingly large quantities of complex condensed matter
systems. In the present paper, we present some preliminary results on the large
scale three-dimensional lattice-Boltzmann simulation of binary immiscible fluid
flows through a porous medium derived from digitised x-ray microtomographic
data of Bentheimer sandstone, and from the study of the same fluids under
shear. Simulations on such scales can benefit considerably from the use of
computational steering and we describe our implementation of steering within
the lattice-Boltzmann code, called LB3D, making use of the RealityGrid steering
library. Our large scale simulations benefit from the new concept of capability
computing, designed to prioritise the execution of big jobs on major
supercomputing resources. The advent of persistent computational grids promises
to provide an optimal environment in which to deploy these mesoscale simulation
methods, which can exploit the distributed nature of compute, visualisation and
storage resources to reach scientific results rapidly; we discuss our work on
the grid-enablement of lattice-Boltzmann methods in this context.Comment: 17 pages, 6 figures, accepted for publication in
Phil.Trans.R.Soc.Lond.
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