Making Human Connectome Faster: GPU Acceleration of Brain Network Analysis

2010 IEEE 16th International Conference on Parallel and Distributed Systems Pub Date : 2010-12-08 DOI:10.1109/ICPADS.2010.105

Di Wu, Tianji Wu, Yi Shan, Yu Wang, Yong He, Ningyi Xu, Huazhong Yang

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引用次数: 9

Abstract

The research on complex Brain Networks plays a vital role in understanding the connectivity patterns of the human brain and disease-related alterations. Recent studies have suggested a noninvasive way to model and analyze human brain networks by using multi-modal imaging and graph theoretical approaches. Both the construction and analysis of the Brain Networks require tremendous computation. As a result, most current studies of the Brain Networks are focused on a coarse scale based on Brain Regions. Networks on this scale usually consist around 100 nodes. The more accurate and meticulous voxel-base Brain Networks, on the other hand, may consist 20K to 100K nodes. In response to the difficulties of analyzing large-scale networks, we propose an acceleration framework for voxel-base Brain Network Analysis based on Graphics Processing Unit (GPU). Our GPU implementations of Brain Network construction and modularity achieve 24x and 80x speedup respectively, compared with single-core CPU. Our work makes the processing time affordable to analyze multiple large-scale Brain Networks.

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使人类连接组更快:GPU加速脑网络分析

复杂脑网络的研究对于理解人类大脑的连接模式和疾病相关的改变起着至关重要的作用。最近的研究提出了一种利用多模态成像和图理论方法对人脑网络进行建模和分析的无创方法。大脑网络的构建和分析都需要大量的计算。因此，目前大多数关于大脑网络的研究都集中在基于大脑区域的粗略尺度上。这种规模的网络通常由大约100个节点组成。另一方面，更精确和细致的基于体素的大脑网络可能包含20K到100K个节点。针对大规模网络分析的困难，提出了一种基于图形处理单元(GPU)的基于体素的脑网络分析加速框架。与单核CPU相比，我们的大脑网络构建和模块化GPU分别实现了24倍和80倍的加速。我们的工作使得处理时间可以负担得起分析多个大规模脑网络。

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2010 IEEE 16th International Conference on Parallel and Distributed Systems

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