Terahertz spectroscopic material identification using approximate entropy and deep neural network

Yichao Li, Xiaoping Shen, R. Ewing, Jia Li
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引用次数: 6

Abstract

Terahertz spectroscopy and imaging are a rapidly developed technique with important applications in many areas, such as medical imaging, security, chemistry, biochemistry, astronomy, communications, and manufacturing, to name a few. However, terahertz spectroscopy and imaging produce excessively high dimensional data which is prohibitive for common methods developed in the area of image processing. In this paper, we report our recent study on a novel classifier based on feature extraction using approximate entropy (ApEn). The classifier is initiated by analyzing the complexity of the terahertz spectrum, which is then combined with a deep neural network for material classification. Experimental results show that approximate entropy based features have high sensitive for detecting metal matrix composites, the accuracy of identification is up to 96.3%. Related algorithms for ApEn feature extraction and material classification are illustrated. An optimal parameter-embedding dimension, subject to classification accuracy for ApEn is studied.
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基于近似熵和深度神经网络的太赫兹光谱材料识别
太赫兹光谱学和成像技术是一项迅速发展的技术,在许多领域都有重要的应用,如医学成像、安全、化学、生物化学、天文学、通信和制造等。然而,太赫兹光谱和成像产生过高的维度数据,这是禁止在图像处理领域开发的常用方法。在本文中,我们报告了我们最近研究的一种基于近似熵(ApEn)特征提取的新型分类器。分类器通过分析太赫兹光谱的复杂性来启动,然后将其与深度神经网络相结合进行材料分类。实验结果表明,基于近似熵的特征对金属基复合材料具有较高的灵敏度,识别准确率可达96.3%。介绍了ApEn特征提取和材料分类的相关算法。在保证分类精度的前提下,研究了ApEn的最优参数嵌入维数。
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