Generating high-resolution daily soil moisture by using spatial downscaling techniques: a comparison of six machine learning algorithms

•Random forest algorithm achieved superior performance in soil moisture downscaling with high accuracy and robustness.•Regions located in one single climate zone which had mild topography variation and medium vegetation coverage tended to produce downscaled soil moisture with higher accuracy.•DEM, d...

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Bibliographic Details
Published in:Advances in water resources 2020-07, Vol.141, p.103601, Article 103601
Main Authors: Liu, Yangxiaoyue, Jing, Wenlong, Wang, Qi, Xia, Xiaolin
Format: Article
Language:English
Subjects:
Downscaling
ECV soil moisture
Machine learning
Underlying surface
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Summary:•Random forest algorithm achieved superior performance in soil moisture downscaling with high accuracy and robustness.•Regions located in one single climate zone which had mild topography variation and medium vegetation coverage tended to produce downscaled soil moisture with higher accuracy.•DEM, daytime LST, and NDVI were dominant parameters in soil moisture simulation. Tremendous efforts have been made for obtaining surface soil moisture (SM) at high spatial resolutions from microwave-based products via spatial downscaling. In recent years, machine learning has been one of the most advanced techniques in SM spatial downscaling. The performance of a machine learning technique in SM spatial downscaling varies with the algorithm and the underlying surface; however, despite the importance of machine learning for SM downscaling, there are still only few inter-comparisons, particularly over different surfaces. In this study, the performance of multiple machine learning algorithms in downscaling the ECV (the Essential Climate Variable Program initiated by the European Space Agency) SM dataset was validated over different underlying surfaces. Six machine learning algorithms: artificial neural network (ANN), Bayesian (BAYE), classification and regression trees (CART), K nearest neighbor (KNN), random forest (RF), and support vector machine (SVM), were implemented to establish the spatial downscaling models with reliable continuous in-situ SM observations over four case study areas, including the Okalahoma Mesonet (OKM) in North America, Naqu network (NAN) in the Tibetan Plateau, REMEDHUS (REM) network in northeast Spain, and OZNNET (OZN) in southeast Australia. The land surface temperature (LST), normalized difference vegetation index (NDVI), albedo, digital elevation model (DEM), and geographic coordinates were the explanatory variables, and their contributions to the downscaling models over different surfaces were quantified. The conclusions of the experiments can be summarized as follows: (1) The RF achieved excellent performance with a high correlation coefficient and a low regression error. The BAYE and KNN also demonstrated favorable capabilities for SM downscaling; however, the robustness of their algorithms needed further improvements. Numerous abnormal values were obtained in the scale-down process by the ANN, CART, and SVM methods, suggesting their comparative inadequacy in SM downscaling. (2) Downscaled 1-km resolution SM in REM generally presented a
ISSN:0309-1708
1872-9657
DOI:10.1016/j.advwatres.2020.103601