Using Remote Sensing Techniques to Improve Hydrological Predictions in a Rapidly Changing World

Using Remote Sensing Techniques to Improve Hydrological Predictions in a Rapidly Changing World


English[eng]

9783040000000


rainfall monitoring||remote sensing||rain rate estimation||5G||millimeter-wave||E-band||LOS-MIMO||UAV remote sensing||Ephemeral rivers||flood peak discharge||incipient motion||arid ungauged regions||flash flood||Integrated Multi-Satellite Retrievals for Global Precipitation Measurement||Rainfall Triggering Index||Yunnan||ecological water transfer||wetland vegetation ecosystem||surface and groundwater interaction||northwestern China||WRF-3DVar data assimilation||coupled atmospheric-hydrologic system||rainfall-runoff prediction||lumped Hebei model||grid-based Hebei model||WRF-Hydro modeling system||evapotranspiration||model||SWAT||calibration||regression||Sierra Nevada||flux tower||water limitation||vapor pressure deficit||double-mass analysis||coefficient of variability||seasonal ARIMA||MK-S trend analysis||evaporation||LAI||NDVI||urban ecosystem||sponge city||PML-V2||Penman–Monteith equation||Sentinel-2||assimilation frequency||data assimilation||WRF-3DAVR||radar reflectivity||rainfall forecast||urban flood||design rainfall||ungauged drainage basin||RainyDay||IDF formula||hydrological prediction||climate change||land use change