|
|
|
|
|
|
| Hyperspectral Prediction Model of Chlorophyll Content in Sugarcane Leaves Under Stress of Mosaic |
| WANG Jing-yong1, XIE Sa-sa2, 3, GAI Jing-yao1*, WANG Zi-ting2, 3* |
1. College of Mechanical Engineering, Guangxi University, Nanning 530004, China
2. College of Agriculture, Guangxi University, Nanning 530004, China
3. Guangxi Key Laboratory of Sugarcane Biology, Guangxi University, Nanning 530004, China
|
|
|
|
|
Abstract Chlorophyll is a critical evaluation content of sugarcane growth monitoring, especially when diseases infected sugarcane. Accurate estimation of chlorophyll content is beneficial for the early detection and control of diseases, which is of great importance in practical production. In order to determine the best prediction model of chlorophyll content in sugarcane leaves, this study infected sugarcane leaves with mosaic from July to November, 2021 through artificial inoculation of pathogenic bacteria. Among them were 35 infected plants and 35 healthy plants, and two leaves were collected for each pot. Repeat the measurement of the leaf hyperspectral data using the spectrometer. The chlorophyll content of chemical leaves was measured to establish a hyperspectral data set of sugarcane leaves. In this study, five pre-processing methods, SG, MSC, SNV, 1st D and 2nd D, were used to establish the PLSR detection model and determine the best preprocessing method. Based on the optimized pretreatment results, correlation coefficient, SPA and RF were used to select the characteristic bands of chlorophyll content in sugarcane leaves, and the selected bands were combined with BPNN, SVR and KNN to establish chlorophyll prediction models. The results showed that the PLSR model based on SG treatment has the highest accuracy R2p=0.995 2, and the RMSEp=0.235 3 mg·cm-2. The model combined with the BPNN algorithm using RF screening was the optimal prediction model of chlorophyll content in sugarcane leaves under mosaic disease stress, the decision coefficient of the SG-RF-BPNN model was R2p=0.996 4, and the RMSEp=0.205 8 mg·cm-2, which had high accuracy and predictive power. It will provide a theoretical basis for the accurate and injury-free disease stress detection of large-scale sugarcane.
|
|
Received: 2022-05-03
Accepted: 2022-08-12
|
|
|
|
Corresponding Authors:
GAI Jing-yao, WANG Zi-ting
E-mail: jygai@gxu.edu.cn;zitingwang@gxu.edu.cn
|
|
[1] Aguiar N O, Medici L O, Olivares F L, et al. Annals of Applied Biology, 2016, 168(2): 203.
[2] Lipps P E. Mycologia, 1990, 82(5): 663.
[3] YUE Xue-jun, QUAN Dong-ping, HONG Tian-sheng, et al(岳学军, 全东平, 洪添胜, 等). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报), 2015, 31(1): 294.
[4] Yamashita H, Sonobe R, Hirono Y, et al. Scientific Reports, 2020, 10(1): 17360.
[5] SUN Hong, ZHENG Tao, LIU Ning, et al(孙 红, 郑 涛, 刘 宁, 等). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报), 2018, 34(1): 149.
[6] DONG Zhe, YANG Wu-de, ZHU Hong-fen, et al(董 哲, 杨武德, 朱洪芬, 等). Journal of Shangxi Agricultural Sciences(山西农业科学), 2019, 47(5): 751.
[7] An G, Xing M, He B, et al. Remote Sensing, 2020, 12(18): 3104.
[8] Bhadra S, Sagan V, Maimaitijiang M, et al. Remote Sensing, 2020, 12(13): 2082.
[9] LI Chang-chun, SHI Jin-Jin, MA Chun-yan, et al(李长春, 施锦锦, 马春艳, 等). Transactions of the Chinese Society for Agricultural Machinery(农业机械学报), 2021, 52(8): 172.
[10] TANG Yan-lin, WANG Ren-chao, WANG Xiu-zhen, et al(唐延林, 王人潮, 王秀珍, 等). Journal of Sounth China Agricultural University(华南农业大学学报), 2003, 24(1): 4.
[11] Baffi G, Martin E B, Morris A J. Computers and Chemical Engineering, 1999, 23(9): 1293.
[12] Khoshhal J, Mokarram M. International Journal of Environmental Sciences, 2012, 3(3): 1000.
[13] Cover T M, Hart P E. IEEE Transactions on Information Theory, 1967, 13(1): 21.
[14] Fan J, Yue W, Wu L, et al. Agricultural and Forest Meteorology, 2018, 263: 225.
[15] WANG Hai-long, YANG Guo-guo, ZHANG Yu, et al(王海龙, 杨国国, 张 瑜, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2017, 37(7): 2115.
[16] Araújo M C U, Saldanha T C B, Galvão R K H, et al. Chemometrics and Intelligent Laboratory Systems, 2001, 57(2): 65.
[17] Bylander T. Machine Learning, 2002, 48(1-3): 287.
|
| [1] |
LI Xin-ting, ZHANG Feng, FENG Jie*. Convolutional Neural Network Combined With Improved Spectral
Processing Method for Potato Disease Detection[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 215-224. |
| [2] |
TANG Ruo-han1, 2, LI Xiu-hua1, 2*, LÜ Xue-gang1, 2, ZHANG Mu-qing2, 3, YAO Wei2, 3. Transmittance Vis-NIR Spectroscopy for Detecting Fibre Content of
Living Sugarcane[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(08): 2419-2425. |
| [3] |
LÜ Xue-gang1, 2,LI Xiu-hua1, 2*,ZHANG Shi-min2,ZHANG Mu-qing1, JIANG Hong-tao1. A Method for Detecting Sucrose in Living Sugarcane With Visible-NIR Transmittance Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(12): 3747-3752. |
| [4] |
LIU Tan1, 2, XU Tong-yu1, 2*, YU Feng-hua1, 2, YUAN Qing-yun1, 2, GUO Zhong-hui1, XU Bo1. Chlorophyll Content Estimation of Northeast Japonica Rice Based on Improved Feature Band Selection and Hybrid Integrated Modeling[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(08): 2556-2564. |
| [5] |
GAO Jun-feng1, ZHANG Chu1, XIE Chuan-qi1, 2, ZHU Feng-le1, GUO Zhen-hao3, HE Yong1* . Prediction the Soluble Solid Content in Sugarcanes by Using Near Infrared Hyperspectral Iimaging System [J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2015, 35(08): 2154-2158. |
| [6] |
LIU Gui-song1, GUO Hao-song1, PAN Tao1*, WANG Ji-hua2, CAO Gan2 . Vis-NIR Spectroscopic Pattern Recognition Combined with SG Smoothing Applied to Breed Screening of Transgenic Sugarcane [J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2014, 34(10): 2701-2706. |
|
|
|
|
