Su Xiangxiang, Nian Ying, Shaghaleh Hiba, Hamad Amar, Yue Hu, Zhu Yongji, Li Jun, Wang Weiqiang, Wang Hong, Ma Qiang, Liu Jikai, Li Xinwei, Alhaj Hamoud Yousef
College of Resource and Environment, Anhui Science and Technology University, Fengyang, China.
College of Environmental, Hohai University, Nanjing, China.
Front Plant Sci. 2024 May 10;15:1404238. doi: 10.3389/fpls.2024.1404238. eCollection 2024.
The Soil Plant Analysis Development (SPAD) is a vital index for evaluating crop nutritional status and serves as an essential parameter characterizing the reproductive growth status of winter wheat. Non-destructive and accurate monitorin3g of winter wheat SPAD plays a crucial role in guiding precise management of crop nutrition. In recent years, the spectral saturation problem occurring in the later stage of crop growth has become a major factor restricting the accuracy of SPAD estimation. Therefore, the purpose of this study is to use features selection strategy to optimize sensitive remote sensing information, combined with features fusion strategy to integrate multiple characteristic features, in order to improve the accuracy of estimating wheat SPAD. This study conducted field experiments of winter wheat with different varieties and nitrogen treatments, utilized UAV multispectral sensors to obtain canopy images of winter wheat during the heading, flowering, and late filling stages, extracted spectral features and texture features from multispectral images, and employed features selection strategy (Boruta and Recursive Feature Elimination) to prioritize sensitive remote sensing features. The features fusion strategy and the Support Vector Machine Regression algorithm are applied to construct the SPAD estimation model for winter wheat. The results showed that the spectral features of NIR band combined with other bands can fully capture the spectral differences of winter wheat SPAD during the reproductive growth stage, and texture features of the red and NIR band are more sensitive to SPAD. During the heading, flowering, and late filling stages, the stability and estimation accuracy of the SPAD model constructed using both features selection strategy and features fusion strategy are superior to models using only a single feature strategy or no strategy. The enhancement of model accuracy by this method becomes more significant, with the greatest improvement observed during the late filling stage, with R increasing by 0.092-0.202, root mean squared error (RMSE) decreasing by 0.076-4.916, and ratio of performance to deviation (RPD) increasing by 0.237-0.960. In conclusion, this method has excellent application potential in estimating SPAD during the later stages of crop growth, providing theoretical basis and technical support for precision nutrient management of field crops.
土壤植物分析发展指数(SPAD)是评估作物营养状况的重要指标,也是表征冬小麦生殖生长状况的关键参数。对冬小麦SPAD进行无损且准确的监测,对指导作物营养精准管理起着至关重要的作用。近年来,作物生长后期出现的光谱饱和问题已成为制约SPAD估算精度的主要因素。因此,本研究旨在利用特征选择策略优化敏感遥感信息,并结合特征融合策略整合多个特征,以提高小麦SPAD的估算精度。本研究开展了不同品种和氮素处理的冬小麦田间试验,利用无人机多光谱传感器获取冬小麦抽穗期、开花期和灌浆后期的冠层图像,从多光谱图像中提取光谱特征和纹理特征,并采用特征选择策略(Boruta和递归特征消除)对敏感遥感特征进行优先级排序。应用特征融合策略和支持向量机回归算法构建冬小麦SPAD估算模型。结果表明,近红外波段与其他波段相结合的光谱特征能够充分捕捉冬小麦生殖生长阶段SPAD的光谱差异,红色和近红外波段的纹理特征对SPAD更为敏感。在抽穗期、开花期和灌浆后期,同时采用特征选择策略和特征融合策略构建的SPAD模型的稳定性和估算精度均优于仅使用单一特征策略或不采用任何策略构建的模型。该方法对模型精度的提升更为显著,在灌浆后期提升最为明显,相关系数R提高了0.092 - 0.202,均方根误差(RMSE)降低了0.076 - 4.916,性能与偏差比(RPD)提高了0.237 - 0.960。综上所述,该方法在作物生长后期SPAD估算方面具有良好的应用潜力,为大田作物精准养分管理提供了理论依据和技术支持。
