Abstract
Daily spatial complete soil moisture (SM) mapping is important for climatic, hydrological, and agricultural applications. The Cyclone Global Navigation Satellite System (CYGNSS) is the first constellation that utilizes the L band signal transmitted by the Global Navigation Satellite System (GNSS) satellites to measure SM. Since the CYGNSS points are discontinuously distributed with a relativity low density, limiting it to map continuous SM distributions with high accuracy. The Moderate-Resolution Imaging Spectroradiometer (MODIS) product (i.e., vegetation index [VI] and land surface temperature [LST]) provides more surface SM information than other optical remote sensing data with a relatively high spatial resolution. This study proposes a point-surface fusion method to fuse the CYGNSS and MODIS data for daily spatial complete SM retrieval. First, for CYGNSS data, the surface reflectivity (SR) is proposed as a proxy to evaluate its ability to estimate daily SM. Second, the LST output from the China Meteorological Administration Land Data Assimilation System (CLDAS, 0.0625° × 0.0625°) and MODIS LST (1 × 1 km) are fused to generate spatial complete and temporally continuous LST maps. An Enhanced Normalized Vegetation Supply Water Index (E-NVSWI) model is proposed to estimate SM derived from MODIS data at high spatial resolution. Finally, the final SM estimation model is constructed from the back-propagation artificial neural network (BP-ANN) fusing the CYGNSS point, E-NWSVI data, and ancillary data, and applied to get the daily continuous SM result over southeast China. The results show that the estimation SM are comparable and promising (R = 0.723, root mean squared error [RMSE] = 0.062 m3 m−3, and MAE = 0.040 m3 m−3 vs. in situ, R = 0.714, RMSE = 0.057 m3 m−3, and MAE = 0.039 m3 m−3 vs. CLDAS). The proposed algorithm contributes from two aspects: (1) validates the CYGNSS derived SM by taking advantage of the dense in situ networks over Southeast China; (2) provides a point-surface fusion model to combine the usage of CYGNSS and MODIS to generate the temporal and spatial complete SM. The proposed approach reveals significant potential to map daily spatial complete SM using CYGNSS and MODIS data at a regional scale.
Highlights
Soil moisture (SM) has a significant impact on the earth’s ecosystem by affecting the hydrological processes and climate changes
The China Meteorological Administration Land Data Assimilation System (CLDAS) soil moisture (SM) is comprised mainly based on Ensemble Kalman Filter (EnKF) and land process models integrating precipitation of atmospheric forcing data and surfaceincident solar radiation data received from hourly outputs of the FY2 geostationary meteorological satellite, and observation data (Zeng et al, 2021)
Due to the design of satellite orbits, gaps exist in daily Soil Moisture Active Passive (SMAP) SM products provided by microwave sensors
Summary
Soil moisture (SM) has a significant impact on the earth’s ecosystem by affecting the hydrological processes and climate changes. Spatial complete and temporal continuous SM products are importantly needed for such applications This reveals the necessity to map and analyze daily complete SM information with high spatial resolution (i.e., 1 × 1 km) in the long term and over a large scale. SM estimated from land surface models (LSMs) [i.e., the Global Land Data Assimilation System (GLDAS) and the China Meteorological Administration Land Data Assimilation System (CLDAS)] has been released for public use, with spatial completeness and temporal continuity (Teuling et al, 2009; Bi et al, 2016; Meng et al, 2017) These products are primarily designed for global or continental scale SM studies, with a relatively low spatial resolution (i.e., 0.25◦ × 0.25◦ for GLDAS and 0.0625◦ × 0.0625◦ for CLDAS). SM information is rarely available at adequate spatial and temporal scales using a single remote sensing method
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