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Liu W, Liu Z, Huang C, Lu M, Liu J, et al. 2016. Statistical analysis of the occurrence and damage of major crop pests and diseases in the past decade. Plant Protection 42(5):1−9,46

Yu J, Schumann AW, Cao Z, Sharpe SM, Boyd NS. 2019. Weed detection in perennial ryegrass with deep learning convolutional neural network. Frontiers in Plant Science 10:1422

Wu Z. 2018. Research on early detection and grading method of soybean mosaic disease based on hyperspectral imaging. Thesis. Zhejiang University of Technology, China

Zhong L. 2021. Detection of tomato greening disease by bioluminescence and hyperspectral imaging. Thesis. Zhejiang University, China

Smigaj M, Gaulton R, Suárez JC, Barr SL. 2019. Combined use of spectral and structural characteristics for improved red band needle blight detection in pine plantation stands. Forest Ecology and Management 434:213−23

Abdulridha J, Ampatzidis Y, Roberts P, Kakarla SC. 2020. Detecting powdery mildew disease in squash at different stages using UAV-based hyperspectral imaging and artificial intelligence. Biosystems Engineering 197:135−48

Liu S, Yu H, Sui Y, Kong L, Yu Z, et al. 2023. Hyperspectral data analysis for classification of soybean leaf diseases. Spectroscopy and Spectral Analysis 43(05):1550−55

Wang X, Deng J, Huang H, Deng Y, Jiang T, et al. 2019. Identification of pests in cotton fields based on hyperspectral data. Journal of South China Agricultural University 40(3):97−103

Riefolo C, Antelmi I, Castrignanò A, Ruggieri S, Galeone C, et al. 2021. Assessment of the hyperspectral data analysis as a tool to diagnose Xylella fastidiosa in the asymptomatic leaves of olive plants. Plants 10(4):683

Uddin MP, Mamun MA, Hossain MA. 2020. PCA-based feature reduction for hyperspectral remote sensing image classification. ITET Technical Review 38(4):377−396

Silalahi DD, Midi H, Arasan J, Mustafa M S, Caliman JP. 2018. Robust generalized multiplicative scatter correction algorithm on pretreatment of near infrared spectral data. Vibrational Spectroscopy 97:55−65

Nason GP. 2010. Wavelet Methods in Statistics with R. New York: Springer. 257 pp. doi: 10.1007/978-0-387-75961-6.

Wu Y, Li X, Zhang Q, Zhou X, Qiu H, et al. 2023. Recognition of spider mite infestations in jujube trees based on spectral-spatial clustering of hyperspectral images from UAVs. Frontiers in Plant Science 14:1078676

Savitzky A, Golay MJE. 1964. Smoothing and differentiation of data by simplified least squares procedures. Analytical Chemistry 36:1627−39

Helland IS, Næs T, Isaksson T. 1995. Related versions of the multiplicative scatter correction method for preprocessing spectroscopic data. Chemometrics and Intelligent Laboratory Systems 29(2):233−41

Saunders C, Stitson MO, Weston J. 2022. Support vector machine. Computer Science 1(4):1−28

Li J, Peng Y , Chen L, Huang W. 2014. Near-infrared hyperspectral imaging combined with CARS algorithm to quantitatively determine soluble solids content in "Y" pear. Spectroscopy and Spectral Analysis 34:1264−69

Qiao S, Tian Y, Wang Q, Song S, Song P. 2021. Nondestructive detection of decayed blueberry based on information fusion of hyperspectral imaging (HSI) and low-field nuclear magnetic resonance (LF-NMR). Computers and Electronics in Agriculture 184:106100

Xu L, Wang X, Chen H, Bo X, Yong H, et al. 2022. Predicting internal parameters of kiwifruit at different storage periods based on hyperspectral imaging technology. Journal of Food Measurement and Characterization 16:3910−25

Araújo MCU, Saldanha TCB, Galvão RKH, Yongeyama T, Chame HC, et al. 2001. The successive projections algorithm for variable selection in spectroscopic multicomponent analysis. Chemometrics and Intelligent Laboratory Systems 57(2):65−73

Gao J, Li X, Zhu F, He Y. 2013. Application of hyperspectral imaging technology to discriminate different geographical origins of Jatropha curcas L seeds. Computers and Electronics in Agriculture 99:186−93

Liu S, Tian Y, Zhang F, Feng D. 2017. Non-destructive detection of apple diseases using hyperspectral images based on quadratic continuous projection method and BP artificial neural network. Food Science 38(08):277−82

Centner V, Massart DL, de Noord OE, de Jong S, Vandeginste BM, et al. 1996. Elimination of uninformative variables for multivariate calibration. Analytical Chemistry 68(21):3851−58

Chen Y, Wang Z, Wang Z. 2017. Novel variable selection method based on uninformative variable elimination and ridge extreme learning machine: CO gas concentration retrieval trial. Spectroscopy and Spectral Analysis 37(01):299−305

Pearson K, Mag P. 1901. On lines and planes of closest fit to systems of points in space. The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science 2:559−72

Johnson DE. 2005. Applied multivariate methods for data analysis. Beijing: Higher Education Press. pp. 93−111

Yu Y, Wang B, Zhang L. 2009. A Fast data-oriented algorithm for Principal Component Analysis. Pattern Recognition and Artificial Intelligence 22(4):568−73

Liu Z, Zhao W. 2021. Research on cross-media correlation analysis method based on semantic and distribution features. Journal of Information Science 40(5):471−78

Liu W, Li Y, Luo J, Li W, Fu S. 2020. Sentiment analysis of Chinese short text based on BERT and BiLSTM. Journal of Taiyuan Normal University (Natural Science Edition) 19(04):52−58

Shi L, Zhang J, Gao Y, Wei L, Tao Y. 2023. Network intrusion detection based on Transformer and BiLSTM. Computer Engineering (03):29−36,57

Xue J, Shen B. 2023. Dung beetle optimizer: a new meta-heuristic algorithm for global optimization. The Journal of Supercomputing 79(7):7305−36

Yuan X, Yang F, Yang T. 2023. UAV 3D path planning method based on adaptive dung beetle algorithm. Radio Engineering 54:928−36

Wu Q, Xu L, Zou Z, Wang J, Zeng Q, et al. 2022. Rapid nondestructive detection of peanut varieties and peanut mildew based on hyperspectral imaging and stacked machine learning models. Frontiers in Plant Science 13:1047479