Abstract
This study attempts to estimate spatial soil moisture in South Korea (99,000 km2) from January 2013 to December 2015 using a multiple linear regression (MLR) model and the Terra moderate-resolution imaging spectroradiometer (MODIS) land surface temperature (LST) and normalized distribution vegetation index (NDVI) data. The MODIS NDVI was used to reflect vegetation variations. Observed precipitation was measured using the automatic weather stations (AWSs) of the Korea Meteorological Administration (KMA), and soil moisture data were recorded at 58 stations operated by various institutions. Prior to MLR analysis, satellite LST data were corrected by applying the conditional merging (CM) technique and observed LST data from 71 KMA stations. The coefficient of determination (R2) of the original LST and observed LST was 0.71, and the R2 of corrected LST and observed LST was 0.95 for 3 selected LST stations. The R2 values of all corrected LSTs were greater than 0.83 for total 71 LST stations. The regression coefficients of the MLR model were estimated seasonally considering the five-day antecedent precipitation. The p-values of all the regression coefficients were less than 0.05, and the R2 values were between 0.28 and 0.67. The reason for R2 values less than 0.5 is that the soil classification at each observation site was not completely accurate. Additionally, the observations at most of the soil moisture monitoring stations used in this study started in December 2014, and the soil moisture measurements did not stabilize. Notably, R2 and root mean square error (RMSE) in winter were poor, as reflected by the many missing values, and uncertainty existed in observations due to freezing and mechanical errors in the soil. Thus, the prediction accuracy is low in winter due to the difficulty of establishing an appropriate regression model. Specifically, the estimated map of the soil moisture index (SMI) can be used to better understand the severity of droughts with the variability of soil moisture.
Highlights
Soil moisture (SM) is an important state variable governing the partitioning of rainfall into runoff and water that infiltrates the soil
The observed precipitation measured from automatic weather stations (AWSs) of the Korea Meteorological Administration (KMA) considered during the simulation period was interpolated using the inverse distance weighting (IDW) method to match the spatial resolution of 1 km
The USDA textural classification, which divides soil into 12 classes, is one of the most widely used soil classification systems, the soil was classified into four types based on the largest proportion of soil in South Korea
Summary
Soil moisture (SM) is an important state variable governing the partitioning of rainfall into runoff and water that infiltrates the soil. SM has been studied in the agricultural field regarding plant growth, water resources field for rainfall-runoff, and meteorological field regarding interactions between the atmosphere and land [2]. There are multiple ways to estimate SM, including in situ networks and satellite remote sensing. Traditional in situ measurements provide valuable information on SM at different soil depths. TDR, tension-measuring, and gravimetric methods are available to measure SM through ground observations. These methods are expensive and time consuming when used on large areas. In situ SM data of point scale are difficult to use as spatial SM [7,8,9]
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