Title :
mD3DOCKxb: A Deep Parallel Optimized Software for Molecular Docking with Intel Xeon Phi Coprocessors
Author :
Qian Cheng ; Shaoliang Peng ; Yutong Lu ; Chengkun Wu ; Haiqiang Wang ; Xin Liu ; Weiliang Zhu ; Zhijian Xu ; Xinben Zhang
Author_Institution :
Sch. of Comput. Sci., Nat. Univ. of Defense Technol., Changsha, China
Abstract :
Molecular docking is a time consuming process, and it requires a substantial amount of computing power. D3DOCkxb was developed for investigating the effects of halogen bond in drug discovery by adding two precise score functions to Auto Dock. The docking accuracy of D3DOCkxb is better than Auto Dock, which can be attributed to a more complicated processing logic of D3DOCkxb. Consequently, it is an even more challenging task to do parallel optimization on D3DOCkxb. In this paper, we developed mD3DOCkxb, a MIC enabled version of D3DOCkxb, which utilizes Intel Xeon Phi, a Many-Integrated Core (MIC) accelerator, to boost the docking performance. We parallelized the Lamarckian Genetic Algorithm (LGA) in D3DOCKxb with OpenMP and port it to MIC with a number of optimization. And 12x to 18x speedup can be achieved, depending on the number of LGA iterations.
Keywords :
biology computing; coprocessors; genetic algorithms; iterative methods; parallel processing; pharmaceutical technology; AutoDock; Intel Xeon Phi coprocessors; LGA iterations; Lamarckian genetic algorithm; MIC; OpenMP; deep parallel optimized software; drug discovery; halogen bond; mD3DOCKxb; many-integrated core accelerator; molecular docking; precise score functions; Acceleration; Accuracy; Coprocessors; Drugs; Microwave integrated circuits; Optimization; Proteins; LGA; MIC; halogen bond; molecular docking; parallelization; speedup;
Conference_Titel :
Cluster, Cloud and Grid Computing (CCGrid), 2015 15th IEEE/ACM International Symposium on
Conference_Location :
Shenzhen
DOI :
10.1109/CCGrid.2015.64
