Abstract
Nitrogen is an essential nutrient element in crop photosynthesis and yield improvement. Thus, it is urgent and important to accurately estimate the leaf nitrogen contents (LNC) of crops for precision nitrogen management. Based on the correlation between LNC and reflectance spectra, the hyperspectral LiDAR (HSL) system can determine three-dimensional structural parameters and biochemical changes of crops. Thereby, HSL technology has been widely used to monitor the LNC of crops at leaf and canopy levels. In addition, the laser-induced fluorescence (LIF) of chlorophyll, related to the histological structure and physiological conditions of green plants, can also be utilized to detect nutrient stress in crops. In this study, four regression algorithms, support vector machines (SVMs), partial least squares (PLS) and two artificial neural networks (ANNs), back propagation NNs (BP-NNs) and radial basic function NNs (RBF-NNs), were selected to estimate rice LNC in booting and heading stages based on reflectance and LIF spectra. These four regression algorithms were used for 36 input variables, including the reflectance spectral variables on 32 wavelengths and four peaks of the LIF spectra. A feature weight algorithm was proposed to select different band combinations for the LNC retrieval models. The determination coefficient (R2) and the root mean square error (RMSE) of the retrieval models were utilized to compare their abilities of estimating the rice LNC. The experimental results demonstrate that (I) these four regression methods are useful for estimating rice LNC in the order of RBF-NNs > SVMs > BP-NNs > PLS; (II) The LIF data in two forms, including peaks and indices, display potential in rice LNC retrieval, especially when using the PLS regression (PLSR) model for the relationship of rice LNC with spectral variables. The feature weighting algorithm is an effective and necessary method to determine appropriate band combinations for rice LNC estimation.
Highlights
Nitrogen is a crucial nutrient element for plant photosynthesis and it plays a key role in crop yield improvement [1]
The experimental results demonstrate that (I) these four regression methods are useful for estimating rice leaf nitrogen contents (LNC) in the order of radial basic function neural networks (NNs) (RBF-NNs) > support vector machines (SVMs) > back propagation NNs (BP-NNs) > partial least squares (PLS); (II) The laser-induced fluorescence (LIF) data in two forms, including peaks and indices, display potential in rice LNC retrieval, especially when using the PLS regression (PLSR) model for the relationship of rice LNC with spectral variables
8, 526 between the observed and estimated LNC based on reflectance spectra.7 of maximum R2 of each method is plotted in the figures
Summary
Nitrogen is a crucial nutrient element for plant photosynthesis and it plays a key role in crop yield improvement [1]. The leaf biochemical contents of crops, especially the leaf nitrogen contents (LNC), was an important indicator of the photosynthetic status, which could be estimated to help with illumination of the ecosystem changes over wide scales [2]. It is urgent and important for Remote Sens. A real-time and nondestructive technique of LNC monitoring of crops has been extensively investigated in the field of remote sensing for precision nitrogen management [4,5,6,7]. These methods can overcome or reduce the issues that passive remote sensing technologies have, such as data redundancy and the effect of irradiation conditions
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