Neural networks for segmentation and clustering of biomagnetical signals

Neural Networks for Signal Processing II Proceedings of the 1992 IEEE Workshop Pub Date : 1992-08-31 DOI:10.1109/NNSP.1992.253678
M. Schlang, Volker Tresp, K. Abraham-Fuchs, W. Harer, P. Weismuller
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引用次数: 6

Abstract

When measuring biomagnetic signals the amount of data required is very large due to modern multichannel sensor arrays. Using the example of the magnetocardiogram (MCG), the authors show how these data can be automatically segmented and clustered with the help of neural algorithms. Self-organizing maps are not suitable for this application due to the character of the measured data. The data are compressed with the help of a special neural network. A very fast learning algorithm is used in the training phase, requiring substantially less computing power than conventional methods. Combined with a hierarchical cluster algorithm, a recognition rate of 100% of extrasystoles in MCG data was achieved.<>
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生物磁信号分割与聚类的神经网络
当测量生物磁信号时,由于现代多通道传感器阵列,所需的数据量非常大。以心脏磁图(MCG)为例,作者展示了如何在神经算法的帮助下自动分割和聚类这些数据。由于测量数据的特性,自组织映射不适合这种应用。数据在一种特殊的神经网络的帮助下被压缩。在训练阶段使用了非常快速的学习算法,所需的计算能力比传统方法少得多。结合分层聚类算法,对MCG数据的超心率识别率达到100%。
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Neural Networks for Signal Processing II Proceedings of the 1992 IEEE Workshop
Neural Networks for Signal Processing II Proceedings of the 1992 IEEE Workshop
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