Efficient SDS Simulations on Multi-GPU Nodes of XSEDE High-End Clusters

Author

Schlachter, Samuel ; Herbein, S. ; Taufer, Michela ; Shuching Ou ; Patel, Surabhi ; Logan, Jeremy S.

Author_Institution

Comput. & Inf. Sci., Univ. of Delaware, Newark, DE, USA

fYear

2013

fDate

22-25 Oct. 2013

Firstpage

116

Lastpage

123

Abstract

Efficiently studying Sodium Dodecyl Sulfate (SDS) molecules´ formations in the presence of different molar concentrations on high-end GPU clusters whose nodes share accelerators exposes us to several challenges, including the need to dynamically adapt the job lengths. Neither virtualization nor lightweight OS solutions can easily support generality, portability, and maintainability in concert. Our solution complements rather than rewrites existing workflow and resource managers with a companion module that complements functions of the workflow manager and a wrapper module that extends functions of the resource managers. Results on the Keene land cluster show how, by using our modules, accelerated SDS simulations more efficiently use the cluster´s GPUs while leading to relevant scientific observations.

Keywords

chemistry computing; graphics processing units; molecules; operating systems (computers); resource allocation; sodium compounds; virtualisation; Keeneland cluster; XSEDE high-end clusters; accelerated SDS simulations; accelerators; high-end GPU clusters; lightweight OS solutions; molar concentrations; multiGPU nodes; resource managers; sodium dodecyl sulfate molecule formations; workflow manager; Computational modeling; Electronic mail; Graphics processing units; Runtime; Torque; Trajectory; Virtualization; GPU programming; Molecular Dynamics; Sodium dodecyl sulfate;

fLanguage

English

Publisher

ieee

Conference_Titel

eScience (eScience), 2013 IEEE 9th International Conference on

Conference_Location

Beijing

Type

conf

DOI

10.1109/eScience.2013.22

Filename

6683898