Abstract
Accurate and timely crop yield estimation is critical for food security and sustainable development. The rapid development of unmanned aerial vehicles (UAVs) offers a new approach to acquire high spatio-temporal resolution imagery of farmland at a low cost. In order to realize the full potential of UAV platform and sensor, machine learning has been introduced to estimate crop yield, but the shortages of field measurements have troubled researchers. In this article, the CW-RF model, a new wheat yield estimation model suitable for the North China plain, was established using random forest, and the crop growth model (the CERES-wheat model) was chosen to simulate abundant training samples for random forest at field plot scale. According to CERES-wheat model simulation, the leaf area index (LAI) and leaf nitrogen content (LNC) at the wheat jointing and heading stages were selected as the most sensitive parameters, and were retrieved from UAV hyperspectral imagery using the directional second derivative and angular insensitivity vegetation index methods, respectively. Then the retrieved LAI and LNC results were input into the CW-RF model to estimate winter wheat yield. The field validation in Luohe, Henan showed that the root-mean-squared error of the retrieved LAI and LNC were 6.27% and 12.17% at jointing stages, 9.21% and 13.64% at heading stages, respectively. The RMSE of estimated yield was 1,008.08 kg/ha, and the mean absolute percent error of estimated yield was 9.36%, demonstrating the available of the CW-RF model in wheat yield estimation at field plot scale. Apart from Luohe, validations in some other fields (e.g., Xiaotangshan, Beijing), prove the wide applicability of the CW-RF model. In addition, the UAV hyperspectral data were found to significantly improve the retrieval accuracy, and further improve CW-RF model estimation accuracy. In conclusion, this article showed that the CERES-Wheat model simulation can be important data source for machine learning-based wheat yield estimation model at field plot scale, and the hyperspectral sensor mounted on a UAV is a feasible remote sensing data acquisition mode for winter wheat growth monitoring and yield estimation.
Highlights
CROP yield is one of the most critical issues affecting national economic development and food security [1], [2]
Numerous studies have taken an empirical approach based on vegetation indices [7] – [9], and showed that there is a linear relationship between crop yield and vegetation indices such as the normalized difference vegetation index (NDVI), a soil-adjusted vegetation index (SAVI), and green vegetation index (GVI)
The jointing and heading stages were identified as the two key growth periods, and the leaf area index (LAI) and leaf nitrogen content (LNC) were chosen as the main growth parameters for winter wheat yield estimation
Summary
CROP yield is one of the most critical issues affecting national economic development and food security [1], [2]. Since the 1970s, satellite remote sensing data have been broadly used for non-destructive crop yield estimation in large region scale [5], [6]. Some studies concentrated on the empirical models which depended on the relationships between these parameters retrieved from remote sensing and crop yield to estimate the final crop yield [14] [15]. These models have successfully estimated the crop yield in the region scale from satellite imagery, and have been widely used due to their simplicity, calculation convenience, and acceptable accuracy. Relationships established in this way are only applicable for local regions and specified time, and seldom involves the mechanism of crop growth
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
