International audienceForce computations are one of the most time consuming part in performing Molecular Dynamics (MD) simulations. Adaptively Restrained Molecular Dynamics (ARMD) makes it possible to perform fewer force calculations by adap-tively restraining particles positions. This paper introduces parallel algorithms for single-pass incremental force computations to take advantage of adaptive restraints using the Message Passage Interface (MPI) standard. The proposed algorithms are implemented and validated in LAMMPS, however, these algorithms can be applied to other MD simulators. We compared our algorithms with LAMMPS for performance and scalability measurements
We report on a parallel version of the Fast Multipole Method (FMM) implemented in the classical mole...
Significant improvements are presented for the molecular dynamics code ls1 mardyn — a linked cell-ba...
This paper describes the techniques and methodologies employed during parallelization of the Molecul...
International audienceForce computations are one of the most time consuming part in performing Molec...
Molecular Dynamics (MD) is often used to simulate large and complex systems. Although, simulating su...
International audienceAdaptively Restrained Molecular Dynamics (ARMD) is a recently introduced parti...
International audienceAdaptively Restrained Molecular dynamics (ARMD) allows users to perform more i...
Les méthodes de dynamique moléculaire (MD pour Molecular Dynamics en anglais) sont utilisées pour si...
International audienceModern parallel architectures require applications to generate massive paralle...
Copyright: © 2015 Materials Research SocietyThis article discusses novel algorithms for molecular-dy...
© 2013 American Physical SocietyThis article introduces a highly parallel algorithm for molecular dy...
Published under license in Journal of Physics: Conference Series.Recently, an alternative strategy f...
We present an optimized parallelization scheme for molecular dynamics simulations of large biomolecu...
The most widely used technique to allow for parallel simulations in molecular dynamics is spatial do...
International audienceThe computation of long-range potentials is one of the demanding tasks in Mole...
We report on a parallel version of the Fast Multipole Method (FMM) implemented in the classical mole...
Significant improvements are presented for the molecular dynamics code ls1 mardyn — a linked cell-ba...
This paper describes the techniques and methodologies employed during parallelization of the Molecul...
International audienceForce computations are one of the most time consuming part in performing Molec...
Molecular Dynamics (MD) is often used to simulate large and complex systems. Although, simulating su...
International audienceAdaptively Restrained Molecular Dynamics (ARMD) is a recently introduced parti...
International audienceAdaptively Restrained Molecular dynamics (ARMD) allows users to perform more i...
Les méthodes de dynamique moléculaire (MD pour Molecular Dynamics en anglais) sont utilisées pour si...
International audienceModern parallel architectures require applications to generate massive paralle...
Copyright: © 2015 Materials Research SocietyThis article discusses novel algorithms for molecular-dy...
© 2013 American Physical SocietyThis article introduces a highly parallel algorithm for molecular dy...
Published under license in Journal of Physics: Conference Series.Recently, an alternative strategy f...
We present an optimized parallelization scheme for molecular dynamics simulations of large biomolecu...
The most widely used technique to allow for parallel simulations in molecular dynamics is spatial do...
International audienceThe computation of long-range potentials is one of the demanding tasks in Mole...
We report on a parallel version of the Fast Multipole Method (FMM) implemented in the classical mole...
Significant improvements are presented for the molecular dynamics code ls1 mardyn — a linked cell-ba...
This paper describes the techniques and methodologies employed during parallelization of the Molecul...