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用冠层叶色偏态分布模式RGB模型预测大豆产量
引用本文:张佩, 陈郑盟, 马顺登, 尹帝, 江海东. 用冠层叶色偏态分布模式RGB模型预测大豆产量[J]. 农业工程学报, 2021, 37(9): 120-126. DOI: 10.11975/j.issn.1002-6819.2021.09.014
作者姓名:张佩  陈郑盟  马顺登  尹帝  江海东
作者单位:1.南京农业大学农业部作物生理生态与生产管理重点实验室、江苏省现代作物生产协同创新中心、国家信息农业工程技术中心,南京 210095;2.江苏省气象局,南京 210008;3.福建省烟草公司龙岩市公司,龙岩 364000
基金项目:国家重点研发计划课题(2018YFD1000900);江苏省333工程高层次人才培养科研项目和江苏省气象局科技项目(KM201905)
摘    要:为了探索加色混色(Red-Green-Bule,RGB)模型偏态分布模式在大豆产量预测上的可行性,并验证其在不同肥料运筹、不同品种上的通用性,该研究选用曲茎和徐豆18两个大豆品种,设计了不同种植密度和氮肥水平的大田裂区试验,以无人机搭载数码摄像机,在花期及以后的2个重要生殖生长期采集大豆冠层数据.研究证实了大豆冠层数码...

关 键 词:UVA    图像分析  大豆  RGB图像  偏态参数  产量预估
收稿时间:2021-03-15
修稿时间:2021-05-01

Prediction of soybean yield by using RGB model with skew distribution pattern of canopy leaf color
Zhang Pei, Chen Zhengmeng, Ma Shundeng, Yin Di, Jiang Haidong. Prediction of soybean yield by using RGB model with skew distribution pattern of canopy leaf color[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2021, 37(9): 120-126. DOI: 10.11975/j.issn.1002-6819.2021.09.014
Authors:Zhang Pei  Chen Zhengmeng  Ma Shundeng  Yin Di  Jiang Haidong
Affiliation:1.Key Laboratory of Crop Physiology and Ecology in Southern China, Ministry of Agriculture, Jiangsu Collaborative Innovation Center for Modern Crop Production, National Engineering and Technology Center for Information Agriculture, Nanjing Agricultural University, Nanjing 210095, China;2.Jiangsu Meteorological Bureau, Nanjing 210008, China;3.Longyan Company of Fujian Provincial Tobacco Corporation, Longyan 364000, China
Abstract:With the increasing maturity of digital imaging technology and the increasing popularity of high resolution camera equipment, the advantages of high resolution and low cost have prompted the use of digital imaging technology to conduct more qualitative and quantitative descriptions of phenotypic traits for plant appearance. The RGB model is the most commonly used color representation for digital images. In order to explore the feasibility of using color gradation distribution parameters of the RGB model in soybean yield prediction, and to verify the universality of the method in different fertilizer operations and varieties, two soybean varieties, Qujing and Xudou 18, were selected to design field fissure experiments with different densities and nitrogen fertilizer levels in this study. Digital cameras were carried by Unmanned Aerial Vehicle (UAV) to collect soybean canopy digital images during three important reproductive growth stages. The results showed that the cumulative distribution of canopy color gradation of soybean at the florescence, pod-setting and grain-filling stages, all conformed to the skewed distribution, and a total of 20 Color Gradation Skewness-Distribution (CGSD) parameters were obtained by skew analysis. These parameters simultaneously described the shade and distribution of the canopy leaf color. The 20 CGSD parameters were significantly different among the florescence, pod-setting and grain-filling stages. And the variation trend of color depth parameters (mean, median, and mode) was opposite to that of the distribution parameters (skewness and kurtosis). The prediction model of soybean yield by using prediction model multiple stepwise regression method was constructed based on CGSD parameters with P value of 0.012. The model had high estimation accuracy in both the modeling group and the verification groups. The prediction accuracy of the model in modeling group reached 91.30% on average; the average prediction accuracy of 18 plots in the nitrogen operation research validation group was 87.33%. Although the prediction accuracy of the validation group for different varieties was lower than that of the modeling group and the validation group for nitrogen fertilizer operation research, it was also close to 80%. In conclusion, the RGB color model based on skewness distribution provided detailed soybean canopy image information, and the canopy color information quantitatively described systematically from the degree of depth, distribution bias and uniformity. And thus the yield prediction model based on CGSD parameters had high prediction accuracy, which can be widely used to predict yield of soybean grown in different production conditions. At the same time, the use of UAV and digital cameras improves the efficiency of image acquisition, while reduces the cost of image acquisition, which is more conducive to the popularization and application of this method.
Keywords:UAV   nitrogen   image analysis   soybean   RGB models   skewness-distribution parameters   yield prediction
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