Abstract
Satellite retrieval can offer global soil moisture information, such as Advanced Microwave Scanning Radiometer-Earth Observing System (AMSR-E) data. AMSR-E has been used to provide soil moisture all over the world, with a coarse resolution of 25 km × 25 km. The coarse resolution of the soil moisture dataset often hinders its use in local or regional research. This work proposes a new framework based on the random forest (RF) model while using five auxiliary data to downscale the AMSR-E soil moisture data over North China. The downscaled results with a 1 km spatial resolution are verified against in situ measurements. Compared with AMSR-E data, the correlation coefficient of the downscaled data is increased by 0.17, and the root mean squared error, mean absolute error, and unbiased root mean square error are reduced by 0.02, 0.01, and 0.03 m3/m3, respectively. In addition, the comparison results with Multiple Linear Regression and Support Vector Regression downscaled data show that the proposed method significantly outperforms the other two methods. The feasibility of our model is well supported by the importance analysis and leave-one-out analysis. Our study, which combines RF with spatiotemporal search algorithms and efficient auxiliary data, may provide insights into soil moisture downscaling in large areas with various surface characteristics and climatic conditions.
Highlights
Soil moisture plays a considerable part in the process of global water and energy balance [1], affecting many fields, such as hydrology, meteorology, and agriculture
Albedo, Normalized difference vegetation index (NDVI), Land surface temperature (LST), and precipitation data were used as input variables in the random forest (RF)-based soil moisture (SM) relationship model
The results show the practicability of using these parameters in soil moisture downscaling
Summary
Soil moisture plays a considerable part in the process of global water and energy balance [1], affecting many fields, such as hydrology, meteorology, and agriculture. Soil moisture monitoring has been widely used in drought monitoring [2,3], water resources assessment [4,5], crop yield estimation [6], weather forecasting, and hydrological simulation [7,8]. Obtaining accurate and high-resolution soil moisture data is of great significance for ecosystem balance research and coping with climate change [9,10]. The rapid growth of industrial, irrigation, and domestic water consumption has led to a sharp increase in water resource consumption, which in turn has led to more serious droughts in northern China [11].
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