Abstract
Visible-near-infrared (vis-NIR) and X-ray fluorescence (XRF) are key technologies becoming pervasive in proximal soil sensing (PSS), whose fusion holds promising potential to improve the estimation accuracy of soil attributes. In this paper, we examine different data fusion methods for the prediction of key soil fertility attributes including pH, organic carbon (OC), magnesium (Mg), and calcium (Ca). To this end, the vis-NIR and XRF spectra of 267 soil samples were collected from nine fields in Belgium, from which the soil samples of six fields were used for calibration of the single-sensor and data fusion models while the validation was performed on the remaining three fields. The first fusion method was the outer product analysis (OPA), for which the outer product (OP) of the two spectra is computed, flattened, and then subjected to partial least squares (PLS) regression model. Two versions of OPA were evaluated: (i) OPA-FS in which the full spectra were used as input; and (ii) OPA-SS in which selected spectral ranges were used as input. In addition, we examined the potential of least squares (LS) and Granger–Ramanathan (GR) analyses for the fusion of the predictions provided by the single-sensor PLS models. Results demonstrate that the prediction performance of the single-sensor PLS models is improved by GR in addition to the LS fusion method for all soil attributes since it accounts for residuals. Resorting to LS, the largest improvements compared to the single-sensor models were obtained, respectively, for Mg (residual prediction deviation (RPD) = 4.08, coefficient of determination (R2) = 0.94, ratio of performance of inter-quantile (RPIQ) = 1.64, root mean square error (RMSE) = 4.57 mg/100 g), OC (RPD = 1.79, R2 = 0.69, RPIQ = 2.82, RMSE = 0.16%), pH (RPD = 1.61, R2 = 0.61, RPIQ = 3.06, RMSE = 0.29), and Ca (RPD = 3.33, R2 = 0.91, RPIQ = 1, RMSE = 207.48 mg/100 g). OPA-FS and OPA-SS outperformed the individual, GR, and LS models for pH only, while OPA-FS was effective in improving the individual sensor models for Mg as well. The results of this study suggest LS as a robust fusion method in improving the prediction accuracy for all the studied soil attributes.
Highlights
During recent decades, precision agriculture (PA) has emerged as a solution to increase farming efficiency while taking resource limitations and environmental conservation into account [1]
X-ray fluorescence (XRF) spectroscopy and theirIn this fusion were evaluated in an analysis of soil pH, organic carbon (OC), Mg, and Ca using 267 soil samples from a robust fusion method in terms of improving the predictio nine fields in Belgium
Partial least squares regression (PLS) with different pre-processing schemes was examined for modeling individual sensor data with considering and without variable single-sensor models
Summary
Precision agriculture (PA) has emerged as a solution to increase farming efficiency while taking resource limitations and environmental conservation into account [1]. Spectroscopy is one of the methods that is becoming pervasive in PA due to its potential in evaluating the properties of soils and plants [2,3,4] provided in speedy, cost-effective, and environmentally friendly ways. Reports show that the visible frared (vis-NIR) spectroscopy is the most promising technique in PA, whose in prediction of primary properties is usually better than that of the seconda [5,6,7,8]. Another powerful method of PSS is XRF spectrometry, which is ext in elemental analysis [9]. Its performance in analyzing low-Z e powerful method of PSS is XRF spectrometry, which is less extensively used in[10,11]
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