Abstract
Crop breeding programs generally perform early field assessments of candidate selection based on primary traits such as grain yield (GY). The traditional methods of yield assessment are costly, inefficient, and considered a bottleneck in modern precision agriculture. Recent advances in an unmanned aerial vehicle (UAV) and development of sensors have opened a new avenue for data acquisition cost-effectively and rapidly. We evaluated UAV-based multispectral and thermal images for in-season GY prediction using 30 winter wheat genotypes under 3 water treatments. For this, multispectral vegetation indices (VIs) and normalized relative canopy temperature (NRCT) were calculated and selected by the gray relational analysis (GRA) at each growth stage, i.e., jointing, booting, heading, flowering, grain filling, and maturity to reduce the data dimension. The elastic net regression (ENR) was developed by using selected features as input variables for yield prediction, whereas the entropy weight fusion (EWF) method was used to combine the predicted GY values from multiple growth stages. In our results, the fusion of dual-sensor data showed high yield prediction accuracy [coefficient of determination (R2) = 0.527–0.667] compared to using a single multispectral sensor (R2 = 0.130–0.461). Results showed that the grain filling stage was the optimal stage to predict GY with R2 = 0.667, root mean square error (RMSE) = 0.881 t ha–1, relative root-mean-square error (RRMSE) = 15.2%, and mean absolute error (MAE) = 0.721 t ha–1. The EWF model outperformed at all the individual growth stages with R2 varying from 0.677 to 0.729. The best prediction result (R2 = 0.729, RMSE = 0.831 t ha–1, RRMSE = 14.3%, and MAE = 0.684 t ha–1) was achieved through combining the predicted values of all growth stages. This study suggests that the fusion of UAV-based multispectral and thermal IR data within an ENR-EWF framework can provide a precise and robust prediction of wheat yield.
Highlights
Bread wheat is one of the most important food crops that feed 40% of the world population (Liu et al, 2020)
The elastic net regression (ENR) algorithm was independently implemented at each growth stage. Instead of using these results to predict the grain yield (GY) individually, we proposed an entropy weight fusion (EWF) model that combines the predicted results from the different growth stages via weights obtained during the model training stage
In accordance with the gray relational analysis (GRA) mechanism, the higher the gray relational degree (GRD) between the main and the reference sequence, the more closely the sequences are related, which indicates a close relationship between the normalized relative canopy temperature (NRCT) and the yield during the multiple growth stages
Summary
Bread wheat is one of the most important food crops that feed 40% of the world population (Liu et al, 2020). The timely and accurate evaluation of the grain yield (GY) before harvest can aid the selection of elite genotypes in large breeding programs (Mcbratney et al, 2005; Panda et al, 2010). Yield advocating traits, such as green biomass, leaf area index (LAI), and chlorophyll contents, have been used for within-season yield prediction (Hassan et al, 2018, 2019a). The nondestructive measurements of the above proxy traits of the GY have been employed to increase the prediction accuracy of crop yield cost-effectively (Yu et al, 2016; Elsayed et al, 2017; Hassan et al, 2019a)
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