计算机系统应用
計算機繫統應用
계산궤계통응용
APPLICATIONS OF THE COMPUTER SYSTEMS
2014年
10期
188-192
,共5页
功能磁共振%功能连接%受限制波兹曼机%稀疏近似
功能磁共振%功能連接%受限製波玆曼機%稀疏近似
공능자공진%공능련접%수한제파자만궤%희소근사
functional magnetic resonance imaging%functional connectivity%restricted boltzmann machine%sparse approximation
人脑功能连通性检测是神经科学研究的重要技术。使用受限制波兹曼机(Restricted Boltzmann Machine, RBM)对大量多被试功能磁共振(functional Magnetic Resonance Imaging, fMRI)数据进行建模可以检测人脑功能连接,但是不能有效检测单被试数据的功能连接。本文研究一种新颖的融合了稀疏近似与 RBM 技术的脑功能连通性检测模型,该模型充分利用fMRI数据的稀疏性,采用稀疏近似理论对fMRI数据进行空间域稀疏近似压缩,然后使用 RBM 建立模型,以检测脑功能连通性。实验结果表明,该融合模型可以有效地提取单被试数据的脑功能时间域混合模型及其相应的脑功能图谱,解决了RBM在单被试数据分析上的瓶颈。
人腦功能連通性檢測是神經科學研究的重要技術。使用受限製波玆曼機(Restricted Boltzmann Machine, RBM)對大量多被試功能磁共振(functional Magnetic Resonance Imaging, fMRI)數據進行建模可以檢測人腦功能連接,但是不能有效檢測單被試數據的功能連接。本文研究一種新穎的融閤瞭稀疏近似與 RBM 技術的腦功能連通性檢測模型,該模型充分利用fMRI數據的稀疏性,採用稀疏近似理論對fMRI數據進行空間域稀疏近似壓縮,然後使用 RBM 建立模型,以檢測腦功能連通性。實驗結果錶明,該融閤模型可以有效地提取單被試數據的腦功能時間域混閤模型及其相應的腦功能圖譜,解決瞭RBM在單被試數據分析上的瓶頸。
인뇌공능련통성검측시신경과학연구적중요기술。사용수한제파자만궤(Restricted Boltzmann Machine, RBM)대대량다피시공능자공진(functional Magnetic Resonance Imaging, fMRI)수거진행건모가이검측인뇌공능련접,단시불능유효검측단피시수거적공능련접。본문연구일충신영적융합료희소근사여 RBM 기술적뇌공능련통성검측모형,해모형충분이용fMRI수거적희소성,채용희소근사이론대fMRI수거진행공간역희소근사압축,연후사용 RBM 건립모형,이검측뇌공능련통성。실험결과표명,해융합모형가이유효지제취단피시수거적뇌공능시간역혼합모형급기상응적뇌공능도보,해결료RBM재단피시수거분석상적병경。
The human brain functional connectivity detection is an important technique in neuroscience research. The restricted boltzmann machine (RBM), modeling on a large amount of multi-subject functional magnetic resonance imaging (fMRI) data, it can discover the brain functional connectivity. However, the former method with restriction of the huge training data, it can not detect the functional connectivity on single-subject data effectively. In this research, a novel functional connectivity detection model taking advantage of the sparsity is presented, which is an effective combination of the spatial-domain sparse approximation theory and the RBM technique. The experimental results demonstrated that the proposed model could effectively discover both the temporal dynamic model and the corresponding spatial functional maps on the single-subject data, which settled the the bottleneck of RBM.