| 光谱学与光谱分析 |
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| Non-Destructive and Fast Identification of Cotton-Polyester Blend Fabrics by the Portable Near-Infrared Spectrometer |
| LI Wen-xia1, LI Feng1, ZHAO Guo-liang1, TANG Shi-jun2, LIU Xiao-ying1 |
1. School of Material Science and Engineering, Beijing Institute of Fashion and Technology, Beijing 100029, China
2. General Logistics Department Quartermaster Equipment Institute of Peoples Liberation Army, Beijing 100010, China |
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Abstract A series of 376 cotton-polyester (PET) blend fabrics were studied by a portable near-infrared (NIR) spectrometer. A NIR semi-quantitative-qualitative calibration model was established by Partial Least Squares (PLS) method combined with qualitative identification coefficient. In this process, PLS method in a quantitative analysis was used as a correction method, and the qualitative identification coefficient was set by the content of cotton and polyester in blend fabrics. Cotton-polyester blend fabrics were identified qualitatively by the model and their relative contents were obtained quantitatively, the model can be used for semi-quantitative identification analysis. In the course of establishing the model, the noise and baseline drift of the spectra were eliminated by Savitzky-Golay(S-G) derivative. The influence of waveband selection and different pre-processing method was also studied in the qualitative calibration model. The major absorption bands of 100% cotton samples were in the 1 400~1 600 nm region, and the one for 100% polyester were around 1 600~1 800 nm, the absorption intensity was enhancing with the content increasing of cotton or polyester. Therefore, the cotton-polyesters major absorption region was selected as the base waveband, the optimal waveband (1 100~2 500 nm) was found by expanding the waveband in two directions (the correlation coefficient was 0.6, and wave-point number was 934). The validation samples were predicted by the calibration model, the results showed that the model evaluation parameters was optimum in the 1 100~2 500 nm region, and the combination of S-G derivative, multiplicative scatter correction (MSC) and mean centering was used as the pre-processing method. RC (relational coefficient of calibration) value was 0.978, RP (relational coefficient of prediction) value was 0.940, SEC (standard error of calibration) value was 1.264, SEP (standard error of prediction) value was 1.590, and the samples recognition accuracy was up to 93.4%. It showed that the cotton-polyester blend fabrics could be predicted by the semi-quantitative-qualitative calibration model.
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Received: 2013-11-20
Accepted: 2014-03-15
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Corresponding Authors:
LI Wen-xia
E-mail: liwenxia307@163.com
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[1] Mishra A R, Karimi D, Ehsani R, et al. Transactions of the ASABE, 2012, 55 (2):711.
[2] Bittner L K H. Journal of Pharmaceutical and Biomedical Analysis, 2011, 54: 1059.
[3] Wu G F, He Y. Western Psychologist, 2010, 30(2): 331.
[4] Chris Heil. Nutraceutical Business & Technology, 2010, 6(1): 46.
[5] Hu Y, Tian X, Liu L, et al. China Journal of Chinese Materia Medica, 2012, 37(8): 1066.
[6] Zhao Guoliang, Xu Jing. Wool Textile Journal, 2006, 1: 42.
[7] James Rodgers, Keith Beck. Textile Research Journal, 2009, 79(8): 675.
[8] Wang Jingli, Geng Xiang, Gui Jiaxiang, et al. Shanghai Textile Science & Technology, 2013, 41: 5.
[9] GUI Jia-xiang, GENG Xiang, YAO Lei, et al. Journal of Textile Research, 2012, 33(4).
[10] FENG Hong-nian, GAN Lin, JIN Shang-zhong. Laser & Infrared, 2005, 35(10).
[11] Ruckbusch C, Orhan F, Durand A, et al. Applied Spectroscopy, 2006, 5:60.
[12] Durand A, Devos O, Ruckebusch C, et al. Analytica Chimica Acta, 2007, 595: 72.
[13] CHU Xiao-li, YUAN Hong-fu, LU Wan-zhen. Progress in Chemistry, 2004, 7:16.
[14] LIU Yan-yun, HU Chang-qin. Chinese Journal of Pharmaceutical Analysis, 2010, 30(5):968. |
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