| 光谱学与光谱分析 |
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| Study on Spectral Measurement Methods in Identification of Maize Variety Authenticity Based on Near Infrared Spectra of Single Kernels |
| JIA Shi-qiang1, GUO Ting-ting2, TANG Xing-tian1, SI Ge1, YAN Yan-lu1, AN Dong1* |
1. College of Information and Electrical Engineering, China Agricultural University, Beijing 100083, China
2. National Maize Improvement Center of China, China Agricultural University, Beijing 100193, China |
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Abstract In order to establish the better maize variety identification models based on single kernel samples, the near-infrared spectral measurement methods were studied by comparing the direction of the maize seed’s embryo, diffuse reflectance and transmission mode, devices of holding the sample according to their impacts on the performance of variety identification models. Partial least squares-discriminant analysis (PLS-DA) was used to compress the pretreated spectral data into 9 variables, and then the identification models were built based on biomimetic pattern recognition (BPR). The results show that with the maize grain’s embryo facing the light source the models can be made perform better than with embryo backing toward the light source, diffuse reflectance mode is better than transmission mode, and small sample pool performs better than the small aperture. The measurement method of acquiring the diffuse reflectance near infrared spectra of maize by small pool with the seed embryo facing the light source can make models have the best performance. The average correct identification rate of the models is 94.6%, and the average correct rejection rates for the varieties not belonging to the models reached 96.5%.
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Received: 2011-04-20
Accepted: 2011-08-26
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Corresponding Authors:
AN Dong
E-mail: andong@semi.ac.cn, anclear@gmail.com
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[1] ZHAO Jiu-ran, WANG Rong-huan, SHI Jie-hui, et al(赵久然,王荣焕,史洁慧,等). Crops(作物杂志), 2008, 30: 7.
[2] WANG Qi-xian(王启现). Journal of Maize Sciences(玉米科学), 2008, 16(4): 35.
[3] WANG Wei, YANG Wen-peng, DAI Bao-wei, et al(王 伟,杨文鹏,戴保威,等). Seed(种子), 2008, 27,(1):46.
[4] LI Shang-yu, CHEN Yang, WANG Chun-yan, et al(李尚禹,陈 阳,王春艳,等). Journal of Molecular Science(分子科学学报), 2007, 23(3):220.
[5] TENG Hai-tao, Lü Bo, ZHAO Jiu-ran, et al(滕海涛,吕 波,赵久然,等). Biotechnology Bulletin(生物技术通报), 2009, (1): 1.
[6] YAN Yan-lu, ZHAO Long-lian, HAN Dong-hai, et al(严衍禄,赵龙莲,韩东海,等). Foundation and Application of Near-Infrared Spectroscopy Analysis(近红外光谱分析基础与应用). Beijing:China Light Industry Press(北京:中国轻工业出版社),2005.
[7] ZHOU Guang-hua, ZHU Da-zhou, WANG Cheng(周光华,朱大洲,王 成). Journal of Anhui Agricultural Sciences(安徽农业科学), 2010, 38: 15475.
[8] GUO Ting-ting, WANG Shou-jue, WANG Hong-wu, et al(郭婷婷,王守觉,王红武,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2010, 30(9): 2372.
[9] WANG Feng-ge, ZHAO Jiu-ran, WANG Lu, et al(王凤格,赵久然,王 璐,等). Journal of Agricultural Biotechnology(农业生物技术学报), 2007, 15(6): 964.
[10] CHU Xiao-li, YUAN Hong-fu, LU Wan-zhen(褚小立, 袁洪福, 陆婉珍). Process in Chemistry(化学进展), 2004, 16(4):528.
[11] WANG Shou-jue(王守觉). Acta Electronica Sinica(电子学报), 2002, 30(10): 1417.
[12] AN Dong, WANG Ku, WANG Shou-jue(安 冬,王 库,王守觉). Acta Electronica Sinica(电子学报), 2006, 34(2): 277.
[13] YUAN Hong-fu, CHU Xiao-li, LU Wan-zhen, et al(袁洪福, 褚小立, 陆婉珍, 等). Chinese Journal of Analytical Chemistry(分析化学), 2004, 32(2):255.
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