Abstract
The matrix effect is one of the challenges to be overcome for a successful analysis of soil samples using X-ray fluorescence (XRF) sensors. This work aimed at evaluation of a simple modeling approach consisted of Compton normalization (CN) and multivariate regressions (e.g., multiple linear regressions (MLR) and partial least squares regression (PLSR)) to overcome the soil matrix effect, and subsequently improve the prediction accuracy of key soil fertility attributes. A portable XRF was used for analyzing 102 soil samples collected from two agricultural fields with contrasting soil matrices. Using the intensity of emission lines as input, preprocessing methods included with and without the CN. Univariate regression models for the prediction of clay, cation exchange capacity (CEC), and exchangeable (ex-) K and Ca were compared with the corresponding MLR models to assess matrix effect mitigation. The MLR and PLSR models improved the prediction results of the univariate models for both preprocessing methods, proving to be promising strategies for mitigating the matrix effect. In turn, the CN also mitigated part of the matrix effect for ex-K, ex-Ca, and CEC predictions, by improving the predictive performance of these elements when used in univariate and multivariate models. The CN has not improved the prediction accuracy of clay. The prediction performances obtained using MLR and PLSR were comparable for all evaluated attributes. The combined use of CN with multivariate regressions (MLR or PLSR) achieved excellent prediction results for CEC (R2 = 0.87), ex-K (R2 ≥ 0.94), and ex-Ca (R2 ≥ 0.96), whereas clay predictions were comparable with and without CN (0.89 ≤ R2 ≤ 0.92). We suggest using multivariate regressions (MLR or PLSR) combined with the CN to remove the soil matrix effects and consequently result in optimal prediction results of the studied key soil fertility attributes. The prediction performance observed for this solution showed comparable results to the approach based on the preprogrammed measurement package tested (Geo Exploration package, Bruker AXS, Madison, WI, USA).
Highlights
An accurate characterization of spatiotemporal variation of soil key fertility attributes is important for the successful implementation of precision agriculture (PA) [1]
According to the Brazilian soil fertility classes proposed by Van Raij [41], ex-K in Field 1 ranges from medium to very high content, whereas it ranges from low to medium in Field 2
Ca-Kα slightly increased from 0.92 to 0.93. These results suggest a lower influence of Compton normalization (CN) on X-ray fluorescence (XRF) data obtained from soil samples from the same field, confirming the lower influence of the matrix effect for individual field dataset, compared the dataset of the two fields
Summary
An accurate characterization of spatiotemporal variation of soil key fertility attributes is important for the successful implementation of precision agriculture (PA) [1]. The classical mapping methods based on soil sampling followed by laboratory soil analysis is not a practical and cost-effective approach, especially because a high spatial density sampling is required for a reliable characterization [2,3]. The recent development of proximal soil sensing technologies enabled a fast, cost-effective, easy-to-use, and environmentally friendly way for soil attributes mapping [4,5,6]. These sensing techniques overcome the disadvantage of traditional soil sampling and test methods [3,7]. Reports demonstrated XRF as a promising sensing technology for soil fertility assessment in the PA context [8,9]. The application of XRF sensors as a practical tool for fertility analysis on agricultural soils is still at its early stages of development and further research are needed [18,21], for developing transparent procedures and protocols for XRF data acquisition and modeling, as discussed by Tavares et al [22]
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