Abstract
Mid-season nitrogen (N) application in rice crops can maximize yield and profitability. This requires accurate and efficient methods of determining rice N uptake in order to prescribe optimal N amounts for topdressing. This study aims to determine the accuracy of using remotely sensed multispectral data from satellites to predict N uptake of rice at the panicle initiation (PI) growth stage, with a view to providing optimum variable-rate N topdressing prescriptions without needing physical sampling. Field experiments over 4 years, 4–6 N rates, 4 varieties and 2 sites were conducted, with at least 3 replicates of each plot. One WorldView satellite image for each year was acquired, close to the date of PI. Numerous single- and multi-variable models were investigated. Among single-variable models, the square of the NDRE vegetation index was shown to be a good predictor of N uptake (R 2 = 0.75, RMSE = 22.8 kg/ha for data pooled from all years and experiments). For multi-variable models, Lasso regularization was used to ensure an interpretable and compact model was chosen and to avoid over fitting. Combinations of remotely sensed reflectances and spectral indexes as well as variety, climate and management data as input variables for model training achieved R 2 < 0.9 and RMSE < 15 kg/ha for the pooled data set. The ability of remotely sensed data to predict N uptake in new seasons where no physical sample data has yet been obtained was tested. A methodology to extract models that generalize well to new seasons was developed, avoiding model overfitting. Lasso regularization selected four or less input variables, and yielded R 2 of better than 0.67 and RMSE better than 27.4 kg/ha over four test seasons that weren’t used to train the models.
Highlights
Nitrogen (N) is a key input for plant development due to its role in the production of chlorophyll, which is crucial for photosynthesis [1]
The correlation between each of the ratio spectral indexes (RSIs) and normalized difference spectral indexes (NDSI) and N uptake for the pooled data from all experiments was assessed using the coefficient of determination (R2)
For the normalized difference indexes, the best index is normalized difference red edge (NDRE) = NDSI(nir,re), with R2 = 0.73. These results indicate ratio indexes are at least as good as normalized difference indexes for predicting N uptake
Summary
Nitrogen (N) is a key input for plant development due to its role in the production of chlorophyll, which is crucial for photosynthesis [1]. It has a significant role in attaining crop yield potential [2] and quality [3]. N use efficiencies are often low, which leads to non-optimal production costs [5]. Rice N application can be optimized to meet desired targets [6], such as yield, financial return on N cost [7], quality and protein content [8]. Rice protein is determined by N status, with high levels of N resulting in lower cooked rice quality [8]
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