Selective potentiality maximization for input neuron selection in self-organizing maps

R. Kamimura, Ryozo Kitajima
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引用次数: 9

Abstract

The present paper proposes a new type of information-theoretic method to enhance the potentiality of input neurons for improving the class structure of the self-organizing maps (SOM). The SOM has received much attention in neural networks, because it can be used to visualize input patterns, in particular, to clarify class structure. However, it has been observed that the good performance of visualization is limited to relatively simple data sets. To visualize more complex data sets, it is needed to develop a method to extract main characteristics of input patterns more explicitly. For this, several information-theoretic methods have been developed with some problems. One of the main problems is that the method needs much heavy computation to obtain the main features, because the computational procedures to obtain information content should be repeated many times. To simplify the procedures, a new measure called “potentiality” of input neurons is proposed. The potentiality is based on the variance of connection weights for input neurons and it can be computed without the complex computation of information content. The method was applied to the artificial and symmetric data set and the biodegradation data from the machine learning database. Experimental results showed that the method could be used to enhance a smaller number of input neurons. Those neurons were effective in intensifying class boundaries for clearer class structures. The present results show the effectiveness of the new measure of the potentiality for improved visualization and class structure.
自组织映射中输入神经元选择的选择电位最大化
为了改进自组织映射(SOM)的类结构,本文提出了一种新的增强输入神经元电位的信息论方法。SOM在神经网络中受到了很大的关注,因为它可以用来可视化输入模式,特别是澄清类结构。然而,据观察,可视化的良好性能仅限于相对简单的数据集。为了可视化更复杂的数据集,需要开发一种更明确地提取输入模式主要特征的方法。为此,人们发展了几种信息理论方法,但存在一些问题。该方法的主要问题之一是需要大量的计算来获得主要特征,因为获取信息内容的计算过程需要多次重复。为了简化程序,提出了一种新的测量方法,称为输入神经元的“电位”。电势是基于输入神经元连接权的方差来计算的,不需要复杂的信息量计算。将该方法应用于人工对称数据集和机器学习数据库中的生物降解数据。实验结果表明,该方法可用于增强较少数量的输入神经元。这些神经元有效地强化了阶级界限,使阶级结构更加清晰。目前的结果表明了新测量方法在改进可视化和类结构方面的有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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