Abstract
Visible and near-infrared (VIS–NIR) spectroscopy has been extensively applied to estimate soil organic matter (SOM) in the laboratory. However, if field/moist VIS–NIR spectra can be directly applied to estimate SOM, then much of the time and labor would be avoided. Spectral derivative plays an important role in eliminating unwanted interference and optimizing the estimation model. Nonetheless, the conventional integer order derivatives (i.e., the first and second derivatives) may neglect some detailed information related to SOM. Besides, the full-spectrum generally contains redundant spectral variables, which would affect the model accuracy. This study aimed to investigate different combinations of fractional order derivative (FOD) and spectral variable selection techniques (i.e., competitive adaptive reweighted sampling (CARS), elastic net (ENET) and genetic algorithm (GA)) to optimize the VIS–NIR spectral model of moist soil. Ninety-one soil samples were collected from Central China, with their SOM contents and reflectance spectra measured. Support vector machine (SVM) was applied to estimate SOM. Results indicated that moist spectra differed greatly from dried ground spectra. With increasing order of derivative, the spectral resolution improved gradually, but the spectral strength decreased simultaneously. FOD could provide a better tool to counterbalance the contradiction between spectral resolution and spectral strength. In full-spectrum SVM models, the most accurate estimation was achieved by SVM model based on 1.5-order derivative spectra, with validation R2 = 0.79 and ratio of the performance to deviation (RPD) = 2.20. Of all models studied (different combinations of FOD and variable selection techniques), the highest validation model accuracy for SOM was achieved when applying 1.5 derivative spectra and GA method (validation R2 = 0.88 and RPD = 2.89). Among the three variable selection techniques, overall, the GA method yielded the optimal predictability. However, due to its long computation time, one alternative was to use CARS method. The results of this study confirm that a suitable combination of FOD and variable selection can effectively improve the model performance of SOM in moist soil.
Highlights
Information on soil organic matter (SOM) is required because it is an important indicator of soil fertility and soil quality [1,2]
It could be observed that the whole dataset exhibited wide variation, with minimum, maximum and coefficient of variation (CV) of 8.37 g·kg−1, 45.22 g·kg−1 and 37.27%, respectively, which meaRnemtottehSaents.t2h01e8,s1o0,i4l7s9 amples in the study area were diverse
This study explored the effectiveness of the combinations of fractional order derivative (FOD) and spectral variable selection methods for moist SOM estimation
Summary
Information on soil organic matter (SOM) is required because it is an important indicator of soil fertility and soil quality [1,2]. The estimation of SOM with field/moist spectra may face some challenges: issues with field/moist spectra (e.g., soil particles, soil structure, soil surface and soil water content); difficulties in modeling a suitable VIS–NIR model due to the lack of available field/moist soil spectral libraries; unequal spectral responses in various soil types [4,5,6]. Variations from these factors (just mentioned above) might influence the model accuracy for SOM estimation. Maybe, advanced strategies should be explored to improve the model accuracy
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