Grid-based algorithm to search critical points, in the electron density, accelerated by graphics processing units

Raymundo Hernández-Esparza; Sol Milena Mejía-Chica; Andy D. Zapata-Escobar; Alfredo Guevara-García; Apolinar Martínez-Melchor; Julio M. Hernández-Pérez; Rubicelia Vargas; Jorge Garza

doi:10.1002/jcc.23752

Grid-based algorithm to search critical points, in the electron density, accelerated by graphics processing units

Raymundo Hernández-Esparza
, Sol Milena Mejía-Chica
, Andy D. Zapata-Escobar
, Alfredo Guevara-García
, Apolinar Martínez-Melchor
, Julio M. Hernández-Pérez
, Rubicelia Vargas
, Jorge Garza

Department of Chemistry

Research output: Contribution to journal › Article › peer-review

60 Scopus citations

Abstract

Using a grid-based method to search the critical points in electron density, we show how to accelerate such a method with graphics processing units (GPUs). When the GPU implementation is contrasted with that used on central processing units (CPUs), we found a large difference between the time elapsed by both implementations: the smallest time is observed when GPUs are used. We tested two GPUs, one related with video games and other used for high-performance computing (HPC). By the side of the CPUs, two processors were tested, one used in common personal computers and other used for HPC, both of last generation. Although our parallel algorithm scales quite well on CPUs, the same implementation on GPUs runs around 10× faster than 16 CPUs, with any of the tested GPUs and CPUs. We have found what one GPU dedicated for video games can be used without any problem for our application, delivering a remarkable performance, in fact; this GPU competes against one HPC GPU, in particular when single-precision is used.

Original language	English
Pages (from-to)	2272-2278
Number of pages	7
Journal	Journal of Computational Chemistry
Volume	35
Issue number	31
DOIs	https://doi.org/10.1002/jcc.23752
State	Published - 05 Dec 2014

Keywords

atoms in molecules
electron density
graphics processing units
parallel computing

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10.1002/jcc.23752

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Hernández-Esparza, R., Mejía-Chica, S. M., Zapata-Escobar, A. D., Guevara-García, A., Martínez-Melchor, A., Hernández-Pérez, J. M., Vargas, R., & Garza, J. (2014). Grid-based algorithm to search critical points, in the electron density, accelerated by graphics processing units. Journal of Computational Chemistry, 35(31), 2272-2278. https://doi.org/10.1002/jcc.23752

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title = "Grid-based algorithm to search critical points, in the electron density, accelerated by graphics processing units",

abstract = "Using a grid-based method to search the critical points in electron density, we show how to accelerate such a method with graphics processing units (GPUs). When the GPU implementation is contrasted with that used on central processing units (CPUs), we found a large difference between the time elapsed by both implementations: the smallest time is observed when GPUs are used. We tested two GPUs, one related with video games and other used for high-performance computing (HPC). By the side of the CPUs, two processors were tested, one used in common personal computers and other used for HPC, both of last generation. Although our parallel algorithm scales quite well on CPUs, the same implementation on GPUs runs around 10× faster than 16 CPUs, with any of the tested GPUs and CPUs. We have found what one GPU dedicated for video games can be used without any problem for our application, delivering a remarkable performance, in fact; this GPU competes against one HPC GPU, in particular when single-precision is used.",

keywords = "atoms in molecules, electron density, graphics processing units, parallel computing",

author = "Raymundo Hern{\'a}ndez-Esparza and Mej{\'i}a-Chica, \{Sol Milena\} and Zapata-Escobar, \{Andy D.\} and Alfredo Guevara-Garc{\'i}a and Apolinar Mart{\'i}nez-Melchor and Hern{\'a}ndez-P{\'e}rez, \{Julio M.\} and Rubicelia Vargas and Jorge Garza",

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year = "2014",

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doi = "10.1002/jcc.23752",

language = "English",

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journal = "Journal of Computational Chemistry",

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Hernández-Esparza, R, Mejía-Chica, SM, Zapata-Escobar, AD, Guevara-García, A, Martínez-Melchor, A, Hernández-Pérez, JM, Vargas, R & Garza, J 2014, 'Grid-based algorithm to search critical points, in the electron density, accelerated by graphics processing units', Journal of Computational Chemistry, vol. 35, no. 31, pp. 2272-2278. https://doi.org/10.1002/jcc.23752

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T1 - Grid-based algorithm to search critical points, in the electron density, accelerated by graphics processing units

AU - Hernández-Esparza, Raymundo

AU - Mejía-Chica, Sol Milena

AU - Zapata-Escobar, Andy D.

AU - Guevara-García, Alfredo

AU - Martínez-Melchor, Apolinar

AU - Hernández-Pérez, Julio M.

AU - Vargas, Rubicelia

AU - Garza, Jorge

PY - 2014/12/5

Y1 - 2014/12/5

N2 - Using a grid-based method to search the critical points in electron density, we show how to accelerate such a method with graphics processing units (GPUs). When the GPU implementation is contrasted with that used on central processing units (CPUs), we found a large difference between the time elapsed by both implementations: the smallest time is observed when GPUs are used. We tested two GPUs, one related with video games and other used for high-performance computing (HPC). By the side of the CPUs, two processors were tested, one used in common personal computers and other used for HPC, both of last generation. Although our parallel algorithm scales quite well on CPUs, the same implementation on GPUs runs around 10× faster than 16 CPUs, with any of the tested GPUs and CPUs. We have found what one GPU dedicated for video games can be used without any problem for our application, delivering a remarkable performance, in fact; this GPU competes against one HPC GPU, in particular when single-precision is used.

AB - Using a grid-based method to search the critical points in electron density, we show how to accelerate such a method with graphics processing units (GPUs). When the GPU implementation is contrasted with that used on central processing units (CPUs), we found a large difference between the time elapsed by both implementations: the smallest time is observed when GPUs are used. We tested two GPUs, one related with video games and other used for high-performance computing (HPC). By the side of the CPUs, two processors were tested, one used in common personal computers and other used for HPC, both of last generation. Although our parallel algorithm scales quite well on CPUs, the same implementation on GPUs runs around 10× faster than 16 CPUs, with any of the tested GPUs and CPUs. We have found what one GPU dedicated for video games can be used without any problem for our application, delivering a remarkable performance, in fact; this GPU competes against one HPC GPU, in particular when single-precision is used.

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KW - electron density

KW - graphics processing units

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ER -

Grid-based algorithm to search critical points, in the electron density, accelerated by graphics processing units

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Keywords

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