Reprint

Remote Sensing in Hydrology and Water Resources Management

Edited by
December 2021
512 pages
  • ISBN978-3-0365-2701-7 (Hardback)
  • ISBN978-3-0365-2700-0 (PDF)

This is a Reprint of the Special Issue Remote Sensing in Hydrology and Water Resources Management that was published in

Engineering
Environmental & Earth Sciences
Summary

Water resources are the most valuable resources of sustainable socio-economic development, which is significantly affected by climate change and human activities. Water resources assessment is an urgent need for implementation of the perfect water resources management, but it is difficult to accurately evaluate the quantity and quality of water resources, especially in arid regions and high-altitude regions with sparse gauged data. This book hosts 24 papers devoted to remote sensing in hydrology and water resources management, which summarizes the recent advancement in remote sensing technology for hydrology analysis such as satellite remote sensing for water resources management, water quality monitoring and evaluation using remote sensing data, remote sensing for detecting the global impact of climate extremes, the use of remote sensing data for improved calibration of hydrological models, and so on. In general, the book will contribute to promote the application of remote sensing technology in water resources.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
precipitation datasets; evaluation; spatial scale; temporal scale; climate; Yellow River Basin; data assimilation; WRF; WRFDA; 3DVar; water levels; surface areas; volume variations; hypsometry; bathymetry; lakes; reservoirs; remote sensing; DAHITI; modified strahler approach; airborne LiDAR; DEM; flood inundation; flood map; flood model; LiDAR; terrestrial LiDAR; evapotranspiration; variability; uncertainty; unmanned aerial system; sUAS; multispectral; remote sensing; viticulture; water resources management; California; lake; Tibetan Plateau; hydrological changes; water balance; Chindwin basin; evapotranspiration; hydrological modelling; multi-variable calibration; remote sensing; satellite-based rainfall product; TRMM; temporal resolution; rainfall erosivity; combined approach; multi-objective optimization; modeling uncertainty; model constraint; SWAT; semiarid area; hydrological variations; normalized difference vegetation index; total water storage change; groundwater change; extreme precipitation; estimation; TMPA 3B42-V7; regional frequency analysis; China; satellite datasets; accuracy evaluation; hydrological applicability; SWAT; Bosten Lake Basin; actual evapotranspiration; available water resources; climate change; vegetation greening; VIP-RS model; Lancang-Mekong river basin; MSWEP; AgMERRA; APHRODITE; CHIRPS; PERSIANN; error correction; agricultural water management; crop water consumption; remote sensing model; evapotranspiration allocation; inland water; IWCT; Tianjin; Landsat data; Tarim River Basin; desert-oasis ecotone; land-use change; CA-Markov model; remote sensing in hydrology; precipitation; performance evaluation; GPM; Poyang Lake; Yangtze River; hydrological changes; water balance; precipitation; assimilation; nonparametric modeling; multi-source; n/a; landscape pattern; spatiotemporal changes; influencing factors; watershed; China SE; satellite data; LUE-GPP; SPEI; copula function; conditional probability; soil moisture; neural network; downscaling; microwave data; MODIS data

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