A New Dynamical Domain Decomposition Method for Parallel Molecular Dynamics Simulation on Grid

Abstract

We develop a new Lagrangian material particle -- dynamical domain decomposition method (MPD3) for large scale parallel molecular dynamics (MD) simulation of nonstationary heterogeneous systems on a heterogeneous computing net. MPD3 is based on Voronoi decomposition of simulated matter. The map of Voronoi polygons is known as the Dirichlet tessellation and used for grid generation in computational fluid dynamics. From the hydrodynamics point of view the moving Voronoi polygon looks as a material particle (MP). MPs can exchange particles and information. To balance heterogeneous computing conditions the MP centers should be dependent on timing data. We propose a simple and efficient iterative algorithm which based on definition of the timing-dependent balancing displacement of MP center for next simulation step. The MPD3 program was tested in various computing environments and physical problems. We have demonstrated that MPD3 is a high-adaptive decomposition algorithm for MD simulation. It was shown that the well-balanced decomposition can result from dynamical Voronoi polygon tessellation. One would expect the similar approach can be successfully applied for other particle methods like Monte Carlo, particle-in-cell, and smooth-particle-hydrodynamics.

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