Astrophysical particle simulations with large custom GPU clusters on three continents

R. Spurzem; P. Berczik; I. Berentzen; K. Nitadori; T. Hamada; G. Marcus; A. Kugel; R. Männer; J. Fiestas; R. Banerjee; R. Klessen

doi:10.1007/s00450-011-0173-1

Astrophysical particle simulations with large custom GPU clusters on three continents

R. Spurzem, P. Berczik, I. Berentzen, K. Nitadori, T. Hamada, G. Marcus, A. Kugel, R. Männer, J. Fiestas, R. Banerjee, R. Klessen

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16 Citas (Scopus)

Resumen

We present direct astrophysical N-body simulations with up to six million bodies using our parallel MPICUDA code on large GPU clusters in Beijing, Berkeley, and Heidelberg, with different kinds of GPU hardware. The clusters are linked in the cooperation of ICCS (International Center for Computational Science). We reach about one third of the peak performance for this code, in a real application scenario with hierarchically block time-steps and a core-halo density structure of the stellar system. The code and hardware is used to simulate dense star clusters with many binaries and galactic nuclei with supermassive black holes, in which correlations between distant particles cannot be neglected.

Idioma original	Inglés
Páginas (desde-hasta)	145-151
Número de páginas	7
Publicación	Computer Science - Research and Development
Volumen	26
N.º	3-4
DOI	https://doi.org/10.1007/s00450-011-0173-1
Estado	Publicada - jun. 2011
Publicado de forma externa	Sí

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title = "Astrophysical particle simulations with large custom GPU clusters on three continents",

abstract = "We present direct astrophysical N-body simulations with up to six million bodies using our parallel MPICUDA code on large GPU clusters in Beijing, Berkeley, and Heidelberg, with different kinds of GPU hardware. The clusters are linked in the cooperation of ICCS (International Center for Computational Science). We reach about one third of the peak performance for this code, in a real application scenario with hierarchically block time-steps and a core-halo density structure of the stellar system. The code and hardware is used to simulate dense star clusters with many binaries and galactic nuclei with supermassive black holes, in which correlations between distant particles cannot be neglected.",

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author = "R. Spurzem and P. Berczik and I. Berentzen and K. Nitadori and T. Hamada and G. Marcus and A. Kugel and R. M{\"a}nner and J. Fiestas and R. Banerjee and R. Klessen",

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doi = "10.1007/s00450-011-0173-1",

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AU - Spurzem, R.

AU - Berczik, P.

AU - Berentzen, I.

AU - Nitadori, K.

AU - Hamada, T.

AU - Marcus, G.

AU - Kugel, A.

AU - Männer, R.

AU - Fiestas, J.

AU - Banerjee, R.

AU - Klessen, R.

PY - 2011/6

Y1 - 2011/6

N2 - We present direct astrophysical N-body simulations with up to six million bodies using our parallel MPICUDA code on large GPU clusters in Beijing, Berkeley, and Heidelberg, with different kinds of GPU hardware. The clusters are linked in the cooperation of ICCS (International Center for Computational Science). We reach about one third of the peak performance for this code, in a real application scenario with hierarchically block time-steps and a core-halo density structure of the stellar system. The code and hardware is used to simulate dense star clusters with many binaries and galactic nuclei with supermassive black holes, in which correlations between distant particles cannot be neglected.

AB - We present direct astrophysical N-body simulations with up to six million bodies using our parallel MPICUDA code on large GPU clusters in Beijing, Berkeley, and Heidelberg, with different kinds of GPU hardware. The clusters are linked in the cooperation of ICCS (International Center for Computational Science). We reach about one third of the peak performance for this code, in a real application scenario with hierarchically block time-steps and a core-halo density structure of the stellar system. The code and hardware is used to simulate dense star clusters with many binaries and galactic nuclei with supermassive black holes, in which correlations between distant particles cannot be neglected.

KW - Computational astrophysics

KW - GPU clusters

KW - N-Body simulations

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JO - Computer Science - Research and Development

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ER -

Astrophysical particle simulations with large custom GPU clusters on three continents

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