| 光谱学与光谱分析 |
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| Study on the Identification of Geographical Indication Wuchang Rice Based on the Content of Inorganic Elements |
| LI Yong-le, ZHENG Yan-jie*, TANG Lu, SU Zhi-yi, XIONG Cen |
| Shenzhen Academy of Metrology and Quality Inspection, Shenzhen 518131, China |
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Abstract Wuchang rice is a geographical indication product in China. Due to its high quality and low production, the phenomenon of fake is more and more serious. An effective identification method of Wuchang rice is urgent needed, for the maintenance of its brand image and interest of consumers. Base on the content of inorganic elements which are analyzed by ICP-AES and ICP-MS in rice, the identification model of Wuchang rice is studied combining with principal component analysis (PCA), Fisher discrimination and artificial neural network (ANN) in this paper. The effect on the identification of samples is poor through PCA, while the samples from Wuchang area and other areas can be identified accurately through Fisher discrimination and ANN. The average accurate identification ratio of training and verification set through Fisher discrimination is 93.5%, while the average accurate identification ratio through ANN is 96.4%. The ability to identify of ANN is better than Fisher discrimination. Wuchang rice can be identified accurately through the result of this research which provides a technology for the protection of geographical indications of this product.
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Received: 2014-10-18
Accepted: 2015-02-04
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Corresponding Authors:
ZHENG Yan-jie
E-mail: zhengyj@smq.com.cn
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[1] CHANG Xiang-yang, ZHU Bing-quan, CHEN Nan, et al(常向阳,朱炳泉,陈 南, 等). Journal of Guangzhou University(Natural Science Edition)(广州大学学报·自然科学版), 2007,(06): 49.
[2] Luo M, Zheng Y, Xiong C, et al. Journal of AOAC International, 2013, 96(5): 1048.
[3] Zheng Y, Ruan G, Li B, et al. European Food Research and Technology, 2014, 238(2): 337.
[4] ZHENG Yan-jie, CHEN Su-juan, LI Jin-cai, et al(郑彦婕,陈素娟,李锦才, 等). Food and Fermentation Industries(食品与发酵工业), 2010, (12): 173.
[5] XIA Li-ya, SHEN Shi-gang, LIU Zheng-hao, et al(夏立娅,申世刚,刘峥颢, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2013, 33(1): 102.
[6] Ariyama K, Shinozaki M, Kawasaki A. Journal of Agricultural and Food Chemistry, 2012, 60(7): 1628.
[7] HUANG Xiao-long, HE Xiao-qing, ZHANG Nian, et al(黄小龙,何小青,张 念, 等). Modern Scientific Instruments(现代科学仪器), 2010,(01): 80.
[8] RUAN Gui-hua, DU Fu-you, HUANG Xiao-long, et al(阮贵华,杜甫佑,黄小龙, 等). Food Science(食品科学), 2012, (07): 41.
[9] Ariyama K, Horita H, Yasui A. Journal of Agricultural and Food Chemistry, 2004, 52(19): 5803.
[10] ZHENG Yan-jie, HU Shu-yu, LI Yong-le, et al(郑彦婕,胡书玉,黎永乐, 等). Food and Fermentation Industries(食品与发酵工业), 2012, 38(9): 167.
[11] Fawcett T. Pattern Recognition Letters, 2006, 27(8): 861.
[12] Cheng P, Fan W, Xu Y. Food Control, 2014, 35(1): 153.
[13] CHU Xiao-li(褚小立). Molecular Spectroscopy Analytical Technology Combined with Chemometrics and Its Applications(化学计量学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.
[14] Bergmeir C, Benítez J M. Journal of Statistical Software, 2012, 46(7): 1.
[15] Sommella A, Deacon C, Norton G, et al. Environmental Pollution, 2013, 181: 38. |
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