光谱学与光谱分析 |
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Analysis of Tobacco Color and Location Features Using Visible-Near Infrared Hyperspectral Data |
CAI Jia-yue1, LIANG Miao1, WEN Ya-dong2, YU Chun-xia2, WANG Luo-ping2, WANG Yi2, ZHAO Long-lian1, LI Jun-hui1* |
1. College of Information and Electrical Engineering, China Agricultural University, Beijing 100083, China 2. Technology Center of Yunnan Tobacco Industry Co., Ltd., Kunming 650231, China |
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Abstract In the present paper, six categories of standard industrial grading tobacco provided by Hongta Group are taken as experimental samples, including three different tobacco locations-upper (B), middle(C) and lower(X) parts, with each part containing two kinds of tobacco colors-orange (O) and lemon yellow (L). Two methods including projection model method based on principal component and Fisher criterion (PPF) and support vector machine (SVM) method are used to analyze color and location features of tobacco based on visible-near infrared hyperspectral data. The results of projection model method indicate that in the projection and similarity analysis of tobacco color, location and six tobacco groups classified by color and location, two kinds of color can be fully differentiated, of which the similarity value is -1.000 8. Tobacco from upper and lower parts can also be fully differentiated with similarity value 0.405 3, but they both have intersections with tobacco from middle part. Six tobacco groups classified by color and location can be fully differentiated as well and their projection positions meet the actual external features of tobacco. The results of support vector machine method indicate that in the discriminant analysis of tobacco color, location and six tobacco groups classified by color and location, the average recognition rate of tobacco colors reaches 98%. The average recognition rate of tobacco location is 96%. The average recognition rate of six tobacco groups is 94%. Therefore, it’s feasible to analyze color and location features of tobacco using visible-near infrared hyperspectral data, which can provide reference for tobacco quality evaluation, computer-aided grading and tobacco intelligent acquisition, and also offers a new approach to the analysis of exterior features of other agricultural products.
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Received: 2014-05-25
Accepted: 2014-07-30
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Corresponding Authors:
LI Jun-hui
E-mail: caunir@cau.edu.cn
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