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The Identification Method of Blood by Applying Hilbert Transform to Extract Phase Information of Raman Spectra |
WANG Ning1, 2, WANG Chi1, BIAN Hai-yi2, WANG Jun3, WANG Peng2, BAI Peng-li3, YIN Huan-cai3, TIAN Yu-bing2, GAO Jing2* |
1. School of Mechatronic Engineering and Automation, Shanghai University, Shanghai 200072, China
2. Jiangsu Key Laboratory of Medical Optics, Suzhou Institute of Biomedical Engineering and Technology, Chinese Academy of Sciences, Suzhou 215163, China
3. CAS Key Lab of Bio-Medical Diagnostics, Suzhou Institute of Biomedical Engineering and Technology, Chinese Academy of Sciences, Suzhou 215163, China |
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Abstract A novel method is reported to discriminate human and animal blood by using Raman chemometric analysis. The phase information of Raman spectra was extracted with Hilbert transform and then analyzed with PCA and PLS to improve the accuracy of identification of human and animal blood compared with original spectra. The cluster analysis was made according to the principal component scores scatter plots of blood spectra data or its corresponding phase information. And the appropriate threshold value was set in the PLS-DA model in order to discriminate human and animal blood. The results show that the PCA model of the phase information can identify animal blood and human blood obviously and it exhibits higher recognition rate compared with PCA of original Raman spectra. The PLS-DA indicates that the optimal number of principal components for the phase information is 3, RMSEP and R2 are 0.044 3, 0.993 2, respectively. However, in the PLS model established with the original spectra, the optimal number of principal components is 6, RMSEP and R2 are 0.053 7, 0.990 1, respectively. This indicates that the PLS-DA model of the phase information can make less error by using less principal components. The RMSEP of PLS-DA model built by the phase information of Raman spectra is lower than that of the blood Raman spectra when taking the same number of fitting principal components. In conclusion, the complexity of the PCA and PLS models can be reduced and the recognition accuracy can be improved by extracting the phase information of Raman spectroscopy.
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Received: 2017-06-12
Accepted: 2017-11-24
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Corresponding Authors:
GAO Jing
E-mail: owengaojing@126.com
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[1] LI Kai-kai(李开开). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2016,36(Suppl. 1): 235.
[2] Mclaughlin G, Doty K C, Lednev I K. Forensic Science International, 2014, 238C(5): 91.
[3] Steendam K,De C M, Dhaenens M, et al. Int. J. Legal. Med., 2013, 127(2): 287.
[4] Mclaughlin G, Doty K C, Lednev I K. Forensic Science International, 2014, 238C(5): 91.
[5] Larkin P. Infrared & Raman Spectroscopy, 2011: 117.
[6] Zhang Z M, Chen S, Liang Y Z. The Analyst, 2010, 135(5): 1138.
[7] Bai P, Wang J, Yin H, et al. Analytical Letters, 2016.
[8] Almeida M R D, Correa D N, Rocha W F C, et al. Microchemical Journal, 2013, 109(14): 170.
[9] CHU Xiao-li(褚小立). Molecular Spectroscopy Analytical Technology Combined with Chemometrics and Its Application(化学计量方法与分子光谱分析技术). Beijing: Chemical Industry Press(北京:化学工业出版社),2011.
[10] Lednev I K. Bureau of Justice Statistics, 2012.
[11] Brereton R G, Lloyd G R. Journal of Chemometrics, 2016, 30(4): 134. |
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