LAMMPS' PPPM Long-Range Solver for the Second Generation Xeon Phi

02/14/2017

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Molecular Dynamics is an important tool for computational biologists, chemists, and materials scientists, consuming a sizable amount of supercomputing resources. Many of the investigated systems contain charged particles, which can only be simulated accurately using a long-range solver, such as PPPM. We extend the popular LAMMPS molecular dynamics code with an implementation of PPPM particularly suitable for the second generation Intel Xeon Phi. Our main target is the optimization of computational kernels by means of vectorization, and we observe speedups in these kernels of up to 12x. These improvements carry over to LAMMPS users, with overall speedups ranging between 2-3x, without requiring users to retune input parameters. Furthermore, our optimizations make it easier for users to determine optimal input parameters for attaining top performance.

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LAMMPS' PPPM Long-Range Solver for the Second Generation Xeon Phi

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LAMMPS' PPPM Long-Range Solver for the Second Generation Xeon Phi

Related Research

Long range forces in a performance portable Molecular Dynamics framework

The Vectorization of the Tersoff Multi-Body Potential: An Exercise in Performance Portability

MD-Bench: Engineering the in-core performance of short-range molecular dynamics kernels from state-of-the-art simulation packages

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Optimizing the Performance of Reactive Molecular Dynamics Simulations for Multi-Core Architectures

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