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Multi-algorithm comparison for predicting soil salinity
Wang, Fei ; Shi, Zhou ; Biswas, Asim ; Yang, Shengtian ; Ding, Jianli
Geoderma, 2020-04, Vol.365, p.114211, Article 114211
[Periódico revisado por pares]
Elsevier B.V
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Título:
Multi-algorithm comparison for predicting soil salinity
Autor:
Wang, Fei
;
Shi, Zhou
;
Biswas, Asim
;
Yang, Shengtian
;
Ding, Jianli
Assuntos:
Algorithms
;
Environmental covariates
;
Predictive mapping
;
Random forest
;
Soil salinization
É parte de:
Geoderma, 2020-04, Vol.365, p.114211, Article 114211
Descrição:
•Soil-landscape relationship is dominant factor for accurate predicting soil salinity.•RF was recommended for mapping soil salinity in Xinjiang, China.•No algorithm that is superior for all soil depths.•Best linear and non-linear algorithms were LMSLR and RF.•Complexity of the algorithm did not always increase the stability of the algorithm. Soil salinization is one of the most predominant processes responsible for land degradation globally. However, monitoring large areas presents significant challenges due to strong spatial and temporal variability. Environmental covariates show promise in predicting salinity over large areas provided a reasonable relationship is developed with field measured salinity at few points. While simple regression-based approaches to complex data mining methods have been used in the prediction, a comprehensive comparison of their performances has not been explored, leading to uncertainty in which algorithms to select. This study compares thirteen popularly and non-popularly used algorithms and their performances following four criteria in predicting soil salinity from environmental covariates from Kuqa Oasis from Xinjiang, China. The environmental covariates used for the prediction include principal components of Landsat satellite images at multiple spectral bands, climate factors (referring to land surface temperature), vegetation indices, salinity and soil-related indices, soil moisture indices, DEM derived indices, land use, landform and soil type and categorized them under parameter categories of the SCORPAN (S, soils; C, climate; O, organisms, biotic factor; R, relief; P, parent material; A, age; and N, space) model. The predictive relationships were developed using the algorithms including some previously used ones such as Multiple Linear regression (MLR), Multi-Layer Perceptron-Artificial Neural Network (MLP-ANN), Stochastic Gradient Treeboost (SGT), M5 Model Tree (M5), Multivariate Adaptive Regression Splines (MARS), Classification and Regression Tree (CART), Random Forest (RF), and Support Vector Regression (SVR) and some that have not previously been used in predicting salinity such as Alternating Model Tree (ATM), Gaussian Processes Regression (GPR), Gaussian Radial Basis Functions (GRBF), Least Median Squared Linear Regression (LMSLR), and Reduced Error Pruning Tree (REPTree). Here, 5-fold cross-validation and an independent dataset (30% overall samples) at three depths, 0–10 cm, 10–30 cm, 30–50 cm, were used for parameter optimization and evaluating the performance of algorithms. The performances of these algorithms were compared against multiple criteria, including the parameterization, error level/fitting accuracy (determination coefficient, R2; root mean squared error, RMSE), stability (based on the Pearson correlation coefficient, R; mean absolute percent error, MAPE; root mean squared error, RMSE; Lin’s concordance correlation coefficient, LCCC) and computational efficiency of the algorithms. Finally, the result showed that CSRI is most important parameter for the prediction of soil salinity at the 0–10 cm and 10–30 cm depths, whereas for the 30–50 cm depth interval, VD was the most important predictor. For depths of 0–10 cm, 10–30 cm and 30–50 cm across all models, the model R2 values ranged from 0.60 to 0.74, 0.15 to 0.31, and 0.30 to 0.47, and the RMSE values ranged from 18.87 to 23.49 dS m−1, 9.94 to 13.48 dS m−1 and 3.79 to 7.11 dS m−1. The optimal algorithms at three depths of 0–10 cm, 10–30 cm and 30–50 cm are RF, M5 and GRBF with considering accuracy and stability. After a comprehensive assessment of algorithm performance, we recommend RF for mapping salinity in an arid environment such as that of Xinjiang and elsewhere globally. However, there is no algorithm that can perform ideally for all datasets. Therefore, we suggest that the algorithm should be carefully chosen according to the purposes of the study.
Editor:
Elsevier B.V
Idioma:
Inglês
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