Construction of complex features for predicting soil total nitrogen content based on convolution operations

•Convolutional operations were introduced into screening characteristic wavelengths and constructing the features for predicting STN content.•Construction features with the soil total nitrogen characteristic wavelengths could clearly improve the performance of prediction.•Compare to the other 3 meth...

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Bibliographic Details
Published in:Soil & tillage research 2021-09, Vol.213, p.105109, Article 105109
Main Authors: Wang, Yueting, Li, Minzan, Ji, Ronghua, Wang, Minjuan, Zhang, Yao, Zheng, Lihua
Format: Article
Language:English
Subjects:
Characteristic wavelength
Construction of features
Convolution operations
On-demand fertilization
Spectroscopy
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Summary:•Convolutional operations were introduced into screening characteristic wavelengths and constructing the features for predicting STN content.•Construction features with the soil total nitrogen characteristic wavelengths could clearly improve the performance of prediction.•Compare to the other 3 methods, the embedded method has great potential of overcoming the intercorrelation within the soil spectra.•Convolutional operations can be used to construct the STN features with the small number of STN characteristic wavelengths. On-demand fertilization does not only help to improve fertilizer use efficiency, but also to avoid over-use of chemical fertilizers. Rapid monitoring of the nutrient content constitutes the initial step of on-demand fertilization, and spectroscopy technology is considered as one of the most ideal nondestructive methods to detect the nutrient content. The typical soil spectra contain thousands of wavelengths, these spectral variables often contribute to collinearity and redundancies rather than relevant effective information. To resolve this issue, this paper selected soil total nitrogen (STN) content as the study subject, and the studies were carried out from two aspects, STN characteristic wavelengths screening and STN content prediction model building based on the limited number of independent variables. For the characteristic waveband screening process, four feature extraction methods (including F-test, mutual information, embedded method and deconvolution operation) were used and the results were compared and analyzed. The embedded method was selected as the benchmark method due to its advantages of simple, intuitive and reliable to screen the STN characteristic wavelengths. In the process of building the STN content prediction model, under-fitting problem is a major challenge which is driven by the limitation of soil nitrogen characteristic wavelengths. Towards this, this study proposed a method for constructing complex features for predicting STN content based on convolution operations which shows higher accuracy than those based on Multi-Layer Perceptron Neural Network and polynomial kernel functions. When the number of characteristic wavelengths is 16, the coefficient of determination (R2) is 0.69, root mean square error of prediction (RMSEP) is 4.34 g/kg, and the residual prediction deviation (RPD) is 0.86. After construction with convolution operations (256 features are calculated from these original 16 characteristic wavelengt
ISSN:0167-1987
1879-3444
DOI:10.1016/j.still.2021.105109