Abstract
It is well-documented in the visible and near-infrared reflectance spectroscopy (VNIRS) studies that soil moisture content (SMC) negatively affects the prediction accuracy of soil attributes. This work was undertaken to remove the negative effect of SMC on the on-line prediction of soil organic carbon (SOC). A mobile VNIR spectrophotometer with a spectral range of 305–1700 nm and spectral resolution of 1 nm (CompactSpec, Tec5 Technology, Germany) was used for the spectral measurements at four farms in Flanders, Belgium. A total of 381 fresh soil samples were collected and divided into a calibration set (264) and a validation set (117). The validation samples were processed (air-dried and grind) and scanned with the same spectrophotometer in the laboratory. Three SMC correction methods, namely, external parameter orthogonalization (EPO), piecewise direct standardization (PDS), and orthogonal signal correction (OSC) were used to correct the on-line fresh spectra based-on its corresponding laboratory spectra. Then, the Cubist machine learning method was used to develop calibration models of SOC using the on-line spectra (after correction) of the calibration set. Results indicated that the EPO-Cubist outperformed the PDS-Cubist and the OSC-Cubist, with considerable improvements in the prediction results of SOC (coefficient of determination (R2) = 0.76, ratio of performance to deviation (RPD) = 2.08, and root mean square error of prediction (RMSEP) = 0.12%), compared with the corresponding uncorrected on-line spectra (R2 = 0.55, RPD = 1.24, and RMSEP = 0.20%). It can be concluded that SOC can be accurately predicted on-line using the Cubist machine learning method, after removing the negative effect of SMC with the EPO method.
Highlights
Organic matter and consequentially soil organic carbon (SOC) are key components of soil that affect its physicochemical properties such as soil structure, water holding capacity, and cation exchange capacity (CEC) [1], in addition to its direct influence on soil resistance to erosion [2]
The standard deviation (SD) values were 0.33 for the calibration set and 0.25 for the validation set. This data confirms that the range of SOC content of the validation set is smaller than that the calibration set, which is necessary to ensure the model validity for the studied range in the validation set
This study investigated the use of the Cubist algorithm combined with spectral correction algorithms to remove the effect of soil moisture content (SMC) from on-line collected visible and near infrared (VNIR) spectra and improve the soil organic carbon (SOC) prediction accuracy of spectra collected from multiple fields in Belgium
Summary
Organic matter and consequentially soil organic carbon (SOC) are key components of soil that affect its physicochemical properties such as soil structure, water holding capacity, and cation exchange capacity (CEC) [1], in addition to its direct influence on soil resistance to erosion [2]. The spatial measurement of SOC content is essential for a wide range of environmental and agricultural applications [3]. There is an increasing need for rapid, cost-effective, nondestructive, and sufficiently accurate approaches for predicting SOC under field conditions using either portable or on-line sensing infrastructure [4,5]. Due to the availability of robust and portable detectors, VNIRS has been widely used for the in situ off-line and on-line predictions of various soil properties [7,8,9] including SOC [10,11]
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