Abstract
Accurate precipitation data at a high spatial resolution are essential for hydrological, meteorological, and ecological research at regional scales. This study presented a geostatistical downscaling-calibration procedure to derive the high spatial resolution maps of precipitation over a mountainous watershed affected by a monsoon climate. Based on the relationships between precipitation and other environmental variables, such as the Normalized Difference Vegetation Index (NDVI) and digital elevation model (DEM), a regression model with a residual correction method was applied to downscale the Tropical Rainfall Measuring Mission (TRMM) 3B43 product from coarse resolution (25 km) to fine resolution (1 km). Two methods, geographical difference analysis (GDA) and geographical ratio analysis (GRA), were used to calibrate the downscaled TRMM precipitation data. Monthly 1 km precipitation data were obtained by disaggregating 1 km annual downscaled and calibrated precipitation data using monthly fractions derived from original TRMM data. The downscaled precipitation datasets were validated against ground observations measured by rain gauges. According to the comparison of different regression models and residual interpolation methods, a geographically-weighted regression kriging (GWRK) method was accepted to conduct the downscaling of TRMM data. The downscaled TRMM precipitation data obtained using GWRK described the spatial patterns of precipitation reasonably well at a spatial resolution of 1 km with more detailed information when compared with the original TRMM precipitation. The results of validation indicated that the GRA method provided results with higher accuracy than that of the GDA method. The final annual and monthly downscaled precipitation not only had significant improvement in spatial resolution, but also agreed well with data from the validation rain gauge stations (i.e., R2 = 0.72, RMSE = 161.0 mm, MAE = 127.5 mm, and Bias = 0.050 for annual downscaled precipitation during 2001 to 2015; and R2 = 0.91, RMSE = 22.2 mm, MAE = 13.5 mm, and Bias = 0.048 for monthly downscaled precipitation during 2001 to 2015). In general, the downscaling-calibration procedure is useful for complex mountainous areas with insufficient ground gauges.
Highlights
Precipitation plays a significant role in hydrological and ecological processes as a key component of mass exchange and energy balance [1,2]
The applicability of the original Tropical Rainfall Measuring Mission (TRMM) 3B43 V7 was tested using measurements from 34 rain gauge stations (RGS), which are not included in the Global Precipitation Climatology Centre (GPCC) gauge network used in 3B43 ground calibrations
The dry season, wet season, and whole year were 0.091, 0.057, and 0.062, respectively, which means that the precipitation was overestimated by TRMM 3B43 when compared with observations from RGS
Summary
Precipitation plays a significant role in hydrological and ecological processes as a key component of mass exchange and energy balance [1,2]. The spatial variations of precipitation generally influence vegetation distribution, soil moisture, and surface hydrology [3,4]. Accurate high-spatial-resolution precipitation data (HSPD) are crucial for different meteorological and hydrological applications, especially in data-sparse regions. High-resolution estimates of spatial variability in rainfall fields can identify locally intense storms that could lead to floods [5]. The HSPD can capture more spatially detailed information in drought monitoring when compared to rain gauge observations [6]. HSPD provides a valuable data source for hydrologic modeling and water resources planning purposes [7,8]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
