Identification of Cucumber Disease and Insect Pest Based on
Hyperspectral Imaging
LI Yang1, 2, LI Cui-ling2, 3, WANG Xiu2, 3, FAN Peng-fei2, 3, LI Yu-kang2, ZHAI Chang-yuan1, 2, 3*
1. School of Agricultural Engineering, Jiangsu University, Zhenjiang 212013, China
2. Intelligent Equipment Research Center, Beijing Academy of Agriculture and Forestry Sciences, Beijing 100097, China
3. National Engineering Research Center of Intelligent Equipment for Agriculture, Beijing 100097, China
Abstract:Cucumber downy mildew and libria sativa are serious diseases and insect pests that restrict the development of the cucumber industry. In order to realize the rapid identification of cucumber diseases and insect pests, hyperspectral imaging technology and machine learning were used to explore the characteristic wavelengths of cucumber diseases and insect pests, which laid a foundation for the development of practical cucumber diseases and insect pests identification equipment based on multispectral imaging. This study used a hyperspectral imaging system to collect hyperspectral images of asymptomatic leaves, downy mildew leaves and leaf miner-infected leaves. According to the size of the leaf spot area, several regions of interest (ROI) were selected in the spot area, and the average reflectance data of each ROI was calculated as the original spectral data of the leaf. The samples were divided into training sets and test sets in a 3∶1 ratio by the Kennard-Stone algorithm. Direct orthogonal signal correction (DOSC), multiplicative scatter correction (MSC) and moving average(MA) were used to preprocess the original spectral data. Variable iterative space shrinkage approach (VISSA), competitive adaptive reweight sampling method (CARS), iteratively retains informative variables (IRIV) and shuffled frog leaping algorithm (SFLA) were used to extract characteristic wavelengths, respectively obtains 53, 20, 26, 10 characteristic wavelengths. Then, the successive projections algorithm (SPA) was used to perform secondary dimensionality reduction on the characteristic wavelength data, and finally, the characteristic wavelengths extracted by VISSA-SPA were 455, 536, 615, and 726 nm. The characteristic wavelengths extracted by CARS-SPA were 452, 501, 548 and 578 nm. The characteristic wavelengths extracted by IRIV-SPA were 452, 513, 543 and 553 nm. The characteristic wavelengths extracted by SFLA-SPA are 462, 484, 500 and 550 nm. Support vector machine (SVM), Elman neural network and random forest (RF) modeling were carried out for the full-band and characteristic wavelength data. The results showed that the full band spectral data preprocessed by MA had the best recognition effect, in which the OA of the MA-RF model reached 97.89% and the Kappa coefficient was 0.97. The MA-VISSA-RF model had the best effect among the models built by the data of the characteristic wavelength first extracted, with 98.19% OA and 0.97 Kappa coefficient. MA-IRIV-SPA-SVM model had the best effect among the models built by quadratic dimensionality reduction data, with OA 96.23% and Kappa coefficient 0.95. The results showed that hyperspectral imaging technology had a good effect on the identification of cucumber downy mildew and the insect pest, and 452, 513, 543, 553 nm could be used as the characteristic wavelength for identification of cucumber downy mildew and the insect pest, providing a theoretical basis for developing cucumber disease and insect pest identification equipment, providing a theoretical basis for the development of cucumber disease and insect pest rapid identification equipment.
李 杨,李翠玲,王 秀,范鹏飞,李余康,翟长远. 高光谱成像的黄瓜病虫害识别和特征波长提取方法[J]. 光谱学与光谱分析, 2024, 44(02): 301-309.
LI Yang, LI Cui-ling, WANG Xiu, FAN Peng-fei, LI Yu-kang, ZHAI Chang-yuan. Identification of Cucumber Disease and Insect Pest Based on
Hyperspectral Imaging. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(02): 301-309.
[1] WANG Ying-ying, XIE Xue-wen, LI Bao-ju(王莹莹, 谢学文, 李宝聚). China Vegetables(中国蔬菜), 2015, 1(6): 73.
[2] JI Tao, LIU Hui-ying, XU Jian-ping, et al(纪 涛, 刘慧英, 许建平,等). China Cucurbits and Vegetables(中国瓜菜), 2018, 31(5): 5.
[3] ZHANG Yu-dong, SHI Bao-jun, ZHAO-Xuan, et al(张玉东, 师宝君, 赵 轩, 等). Acta Agriculturae Boreali-occidentalis Sinica(西北农业学报), 2018, 27(9): 1375.
[4] Susič Nik, Žibrat Uroš, Širca Saša, et al. Sensors and Actuators B: Chemical, 2018, 273(10): 842.
[5] Li Y, Luo Z, Wang F, et al. Sensors, 2020, 20(14): 4045.
[6] BAI Xue-bing, YU Jian-shu, FU Ze-tian, et al(白雪冰,余建树,傅泽田,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2019, 39(11): 3592.
[7] QIN Li-feng, ZHANG Tao, ZHANG Xiao-qian(秦立峰, 张 熹, 张晓茜). Transactions of the Chinese Society for Agricultural Machinery(农业机械学报), 2020, 51(11): 212.
[8] XIE Chuan-qi, FANG Xiao-rong, SHAO Yong-ni, et al(谢传奇, 方孝荣, 邵咏妮, 等). Transactions of the Chinese Society for Agricultural Machinery(农业机械学报), 2015, 46(3): 315.
[9] LÜ Xiao-han, JIANG Jin-lin, YANG Jing, et al(吕晓菡, 蒋锦琳, 杨 静,等). Journal of Zhejiang University(Agriculture and Life Sciences)[浙江大学学报(农业与生命科学版)], 2019, 45(6): 760.
[10] ZHAO Li-qing, DUAN Dong-yao, YIN Yuan-yuan, et al(赵丽清, 段东瑶, 殷元元, 等). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报), 2021, 37(19): 284.
[11] BAO Qing-ling, DING Jian-li, WANG Jing-zhe, et al(包青岭, 丁建丽, 王敬哲,等). Arid Land Geography(干旱区地理), 2019, 42(6): 1404.
[12] Deng B C, Yun Y H, Liang Y Z , et al. Analyst, 2014, 139(19): 4836.
[13] PENG Qing-wei, LIU Yun, YU Jian-cheng, et al(彭清维, 刘 芸, 于建成,等). Journal of Tea Science(茶叶科学), 2017, 37(5): 458.
[14] LIANG Kun, LIU Quan-xiang, PAN Lei-qing, et al(梁 琨, 刘全祥, 潘磊庆, 等). Journal of Nanjing Agricultural University(南京农业大学学报), 2018, 41(4): 760.
[15] SUN Jing-jing, YANG Wu-de, FENG Mei-chen, et al(孙晶京, 杨武德, 冯美臣, 等). Journal of Shanxi Agricultural University(Natural Science Edition)[山西农业大学学报(自然科学版)], 2020, 40(5): 120.
[16] CHENG Jie-hong, CHEN Zheng-guang(程介虹, 陈争光). Chinese Journal of Analytical Chemistry(分析化学), 2021, 49(8): 1402.
