Processing of the molecular dynamics model by the parallel computer pax

mura, Niiharigun, Ibarakiken 305, Japan

Algorithms are presented which enable molecular dynamics simulations of liquids to be performed most efficiently on the Cray-i vector processing computer. For 256 atoms interacting via the Lennard-Jones potential the CPU time per step of the simulation is 22 ms.

A concept of vectorization of molecular dynamics Fortran programs for the use of the Cyber 205 machine is presented. It is shown that for calculations with larger particle systems the program runs faster on the 205 than on the Cray-i by about a factor of two. Against conventional computers like the

We describe the implementation of the cell multipole method CMM in a Ž . Ž . complete molecular dynamics MD simulation program MPSim for massively parallel supercomputers. Tests are made of how the program scales with size Ž . Ž . linearly and with number of CPUs nearly linearly in applications invo

## Abstract In this article, we show the ability to use sophisticated computational fluid dynamics (CFD) models as simple and useful tools in the learning process for Fluid Mechanics and Hydraulic Engineering topics. Specifically, we present a comparison between results obtained for a controlled la

## Abstract A detailed description of vector/parallel algorithms for the molecular dynamics (MD) simulation of macromolecular systems on multiple processor, shared‐memory computers is presented. The algorithms encompass three computationally intensive portions of typical MD programs: (__1__) the ev