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Simultaneous Non-Destructive On-Line Detection of Potato Black-Heart Disease and Starch Content Based on Visible/Near Infrared Diffuse Transmission Spectroscopy |
DING Ji-gang1, HAN Dong-hai1, LI Yong-yu1*, PENG Yan-kun1, WANG Qi1, HAN Xi2 |
1. College of Engineering, China Agricultural University, National Agricultural Products Processing Technology and Equipment Research and Development Center, Beijing 100083, China
2. Beijing Weichuang Yingtu Technology Co., Ltd., Beijing 100070,China |
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Abstract The incidence of black-heart disease in post-harvest storage and transportation of potato in China is high, the internal quality is also uneven, and the detection and sorting technology lags behind, which seriously restricts the development of potatoes’ staple food industry. Simultaneous online non-destructive testing of internal quality such as potatoes’ black-heart disease and starch content is of great significance for promoting the strategy of main potato diet in China. Based on the principle of visible/near-infrared diffuse transmission spectroscopy, this study uses a non-destructive on-line detection system built by the laboratory (detection speed is about 4/s), and carries out black heart disease with potato black-heart disease and starch content as internal quality test indicators. Simultaneous non-destructive testing with starch content. The original spectra of 121 healthy potatoes and 116 black-heart potatoes in the 600~1 000 nm band were averaged. The absorbance values of black potato samples in the 600~900 nm band were significantly higher than those of healthy potato samples, and the influence of black heart tissue was observed. The characteristic absorption peak of chlorophyll near 663 nm and the characteristic absorption peak of water near 760 nm of healthy potato were significantly higher than that of black heart potato. Partial Least Squares Discriminant Analysis (PLS-DA) was established based on the original spectrum of healthy potato and black heart potato. At the same time, SG-Smoothing, Standard Normal Transformation (SNV), Multiple Scattering Correction (MSC), First Derivative (FD), SG Smoothing and First Derivative (SG+FD) and other pretreatment methods were applied to the 121 healthy potato spectra. And combined with CARS algorithm to screen the characteristic wavelength, established a Starch Content (SC) Partial Least Squares (PLS) quantitative prediction model. The results showed that the correctness rate of the correction set and verification set of the PLS-DA model of the black-heart potatoes was 97.74% and 98.33%, respectively, and the total discriminant correct rate was 97.89%. The original spectrum was preprocessed by SG smoothing plus first derivative, and then combined with CARS. The PLS model of potato starch content was optimized by algorithm screening. The correlation coefficients of the calibration set and prediction set were 0.928 and 0.908, respectively, and the root means square error was 0.556% and 0.633%, respectively. Finally, the model was built into an online inspection system and externally verified using 50 samples that were not modeled. The correct rate of potato black heart disease was 96%, the correlation coefficient between the starch predicted value and the standard physical and chemical value was 0.893, and the root means square error was 0.713%. It is indicated that potato black-heart disease and other internal quality can be simultaneously detected by on-line non-destructive testing based on potatoes’ diffuse transmission spectroscopy, which provides a technical reference for potatoes’ post-harvest qualities testing and promotion of potatoes’ staple food industry.
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Received: 2019-04-29
Accepted: 2019-09-20
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Corresponding Authors:
LI Yong-yu
E-mail: yyli@cau.edu.cn
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[1] CHEN Meng-shan, WANG Xiao-hu(陈萌山, 王小虎). Agricultural Economic Problems(农业经济问题), 2015, 36(12): 4.
[2] LI Wen-juan, QIN Jun-hong, GU Jian-miao(李文娟, 秦军红, 谷建苗). Chinese Food and Nutrition(中国食物与营养), 2015, 21(7): 5.
[3] Trygve Helgerud, Jens P Wold, Morten B Pedersen, et al. Talanta, 2015, 143:138.
[4] ZHANG Jing-ting, WU Jian-hu, CAI Ya-qin(张婧婷, 吴建虎, 蔡亚琴). Journal of Food Safety and Quality Testing(食品安全质量检测学报),2015, 6(8): 3014.
[5] LI Zhi-xin(李志新). Heilongjiang Agricultural Science(黑龙江农业科学),2011,(11): 78.
[6] LIU Cui-cui, GAO Hong-xiu, LI Zan, et al(刘翠翠, 高红秀, 李 赞,等). Chinese Potato(中国马铃薯),2011, 25(2): 65.
[7] WANG Fan, LI Yong-yu, PENG Yan-kun, et al(王 凡, 李永玉, 彭彦昆,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2018, 38(12): 3736.
[8] WANG Fan, LI Yong-yu, PENG Yan-kun, et al(王 凡, 李永玉, 彭彦昆,等). Journal of Agricultural Machinery(农业机械学报),2018, 49(7): 348.
[9] ZHOU Zhu, LI Xiao-yu, GAO Hai-long(周 竹, 李小昱, 高海龙). Journal of Agricultural Engineering(农业工程学报), 2012, 28(11): 237.
[10] TIAN Fang, PENG Yan-kun, WEI Wen-song, et al(田 芳, 彭彦昆, 魏文松,等). Journal of Agricultural Engineering(农业工程学报),2017, 33(5): 287.
[11] Ainara López-Maestresalas, Janos C Keresztes, Mohammad Goodarzi. Food Control, 2016, 70:229.
[12] GAO Hai-long, LI Xiao-yu, XU Sen-miao, et al(高海龙, 李小昱, 徐森淼,等). Journal of Agricultural Engineering(农业工程学报),2013, 29(15): 279.
[13] ZHOU Zhu, LI Xiao-yu, GAO Hai-long, et al(周 竹, 李小昱, 高海龙,等). Journal of Agricultural Engineering(农业工程学报),2012, 28(11): 237.
[14] XU Chang-jie, CHEN Wen-jun, CHEN Kun-song, et al(徐昌杰, 陈文峻, 陈昆松,等). Biotechnology(生物技术),1998,(2): 41.
[15] BU Xiao-pu, PENG Yan-kun, WANG Wen-xiu,et al(卜晓朴, 彭彦昆, 王文秀). Food Science(食品科学), 2018, 39(16): 227.
[16] Ye Shengfeng, Wang Dong, Min Shungeng. Chemometrics and Intelligent Laboratory Systems,2008,91:194.
[17] Jiang Hui,Zhang Hang,Chen Quansheng,et al. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy,2015,149:1. |
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