HydroSat: geometric quantities of the global water cycle from geodetic satellites

Tourian, Mohammad J.; Elmi, Omid; Shafaghi, Yasin; Behnia, Sajedeh; Saemian, Peyman; Schlesinger, Ron; Sneeuw, Nico

doi:10.5194/essd-14-2463-2022

Cited by 18 publications

(11 citation statements)

References 94 publications

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“…Over the past three decades, satellite altimetry has emerged as a valuable technique for monitoring inland water surfaces and studying the hydrological cycle 23 – 25 . The availability of satellite altimetry data sets has facilitated the development of numerous research initiatives and collaborations, leading to the establishment of valuable databases like Hydroweb 26 , HydroSat 9 and Database for Hydrological Time Series of Inland Waters (DAHITI) 27 . In this study, river water height time series data were collected from the HydroSat ( http://hydrosat.gis.uni-stuttgart.de ) and DAHITI ( https://dahiti.dgfi.tum.de ) databases.…”

Section: Methodsmentioning

confidence: 99%

“…Remote sensing (RS)-based discharge estimates can address the lack of a global discharge record. A promising approach is to develop empirical models, such as rating curves which establish a relationship between the ground-based river discharge and space-based measurements of a hydraulic parameter like river water level 5 – 9 or river width 10 – 11 or even a non-hydraulic quantity such as the ratio of surface reflectance between water and land pixels 12 , 13 . Once the model is developed, discharge can be estimated through remote sensing observations alone.…”

Section: Background and Summarymentioning

confidence: 99%

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Remote Sensing-Based Extension of GRDC Discharge Time Series - A Monthly Product with Uncertainty Estimates

Elmi,

Tourian,

Saemian

et al. 2024

Sci Data

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The Global Runoff Data Center (GRDC) data set has faced a decline in the number of active gauges since the 1980s, leaving only 14% of gauges active as of 2020. We develop the Remote Sensing-based Extension for the GRDC (RSEG) data set that can ingest legacy gauge discharge and remote sensing observations. We employ a stochastic nonparametric mapping algorithm to extend the monthly discharge time series for inactive GRDC stations, benefiting from satellite imagery- and altimetry-derived river width and water height observations. After a rigorous quality assessment of our estimated discharge, involving statistical validation, tests and visual inspection, results in the extension of discharge records for 3377 out of 6015 GRDC stations. The quality of discharge estimates for the rivers with a large or medium mean discharge is quite satisfactory (average KGE value > 0.5) however for river reaches with a low mean discharge the average KGE value drops to 0.33.The RSEG data set regains monitoring capability for 83% of total river discharge measured by GRDC stations, equivalent to 7895 km3/month.

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Section: Methodsmentioning

confidence: 99%

Section: Background and Summarymentioning

confidence: 99%

Remote Sensing-Based Extension of GRDC Discharge Time Series - A Monthly Product with Uncertainty Estimates

Elmi,

Tourian,

Saemian

et al. 2024

Sci Data

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“…Although satellite altimetry missions were developed for ocean surface observations, they have increasingly been applied to 110 observe lakes and rivers (Abdalla et al, 2021;Calmant et al, 2008;Calmant and Seyler, 2006;Yang et al, 2022). Several agencies have already processed their original satellite altimetry data and produced data archives for studying WSEs, including the HydroWeb (Crétaux et al, 2011;Santos da Silva et al, 2010), Hydrosat (Tourian et al, 2016(Tourian et al, , 2022, Database for Hydrological Time Series of Inland Waters (DAHITTI; Schwatke et al, 2015), Global Reservoirs and Lakes Monitor (G-REALM; Birkett and Beckley, 2010), Copernicus Global Land Service (CGLS; Calmant et al, 2013;Crétaux et al, 2011), 115 River & Lake (Birkett et al, 2002), Hidrosat (Santos da Silva et al, 2010;da Silva et al, 2012), and Global River Radar Altimetry Time Series (GRRATS; Coss et al, 2020) archives. In this study, we used satellite altimetry data from HydroWeb for its accessibility and global coverage.…”

Section: Satellite Altimetry Datamentioning

confidence: 99%

AltiMaP: Altimetry Mapping Procedure for Hydrography Data

Revel¹,

Zhou²,

Modi³

et al. 2023

Preprint

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Abstract. Satellite altimetry data are useful for monitoring water surface dynamics, evaluating and calibrating hydrodynamic models, and enhancing river-related variables through optimization or assimilation approaches. However, comparing simulated water surface elevations (WSEs) using satellite altimetry data is challenging due to the difficulty of correctly matching the representative locations of satellite altimetry virtual stations (VSs) to the discrete river grids used in hydrodynamic models. In this study, we introduce an automated altimetry mapping procedure (AltiMaP) that allocates VS locations listed in the HydroWeb database to the Multi-Error Removed Improved Terrain Hydrography (MERIT Hydro) river network. Each VS was flagged according to the land cover of the initial pixel allocation, with 10, 20, 30, and 40 representing river channel, land with the nearest single-channel river, land with the nearest multi-channel river, and ocean pixels, respectively. Then, each VS was assigned to the nearest MERIT Hydro river reach according to geometric distance. Among the approximately 12,000 allocated VSs, most were categorized as flag 10 (71.7 %). Flags 10 and 20 were mainly located in upstream and midstream reaches, whereas flags 30 and 40 were mainly located downstream. Approximately 0.8 % of VSs showed bias, with considerable elevation differences (≥|15|m) between the mean observed WSE and MERIT digital elevation model. These biased VSs were predominantly observed in narrow rivers at high altitudes. Following VS allocation using AltiMaP, the median root mean squared error of simulated WSEs compared to satellite altimetry was 7.86 m. The error rate was much lower (10.6 %) than that obtained using a traditional approach, partly due to bias reduction. Thus, allocating VSs to a river network using the proposed AltiMaP framework improved our comparison of WSEs simulated by the global hydrodynamic model to those obtained by satellite altimetry. The AltiMaP source code (https://doi.org/10.5281/zenodo.7597310) (Revel et al., 2023a) and data (https://doi.org/10.4211/hs.632e550deaea46b080bdae986fd19156) (Revel et al., 2022) are freely accessible online and we anticipate that they will be beneficial to the international hydrological community.

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“…Thanks to these methodologies, a number of studies have employed the satellite multi-mission databases to estimate river discharge (since the pioneering study in an African basin from Coe and Birkett 2004 on Lake Tchad basin, to recent ones such as Papa et al 2010;Paris et al 2016;Tourian et al 2016;Bogning et al 2018;Scherer et al 2020;Pujol et al 2020;Malou et al 2021). Despite the huge contribution provided by multi-mission approaches, the combination of different altimetry measurements represents still a challenge because of the inter-satellite biases (Normandin et al 2018) which impede a straightforward combination of water level measurements (Tourian et al 2022). The inter-satellite bias depends not only on the mission but also on the atmospheric corrections (Fernandes et al 2014) or the retracker algorithm (Kitambo et al 2021), and therefore it cannot be considered global, but it needs to be estimated at regional scale.…”

Section: Radar Altimetry For Understanding the River Flow: Past Curre...mentioning

confidence: 99%

Water Resources in Africa: The Role of Earth Observation Data and Hydrodynamic Modeling to Derive River Discharge

Tarpanelli

Paris²,

Sichangi

et al. 2022

Surv Geophys

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For more than a century, river discharge has been measured indirectly through observations of water level and flow velocity, but recently the number of gauging stations worldwide has decreased and the situation is particularly serious in African countries that suffer more than others from discontinuous and incomplete monitoring. As one of the most vulnerable regions in the world to extreme weather events and global warming, African countries need adequate and reliable monitoring. Decades of available Earth Observations data represent a tool complementary to the hydro-monitoring network and, in recent decades, they have demonstrated their potential, especially for data-poor regions. In this paper, a review of methods for hydrological and hydraulic modeling and for estimating river discharge by the use of satellite data, specifically radar altimetry and optical sensors, is provided, with particular focus on their role in the climate changes monitoring. More emphasis is placed on their relevance on African basins highlighting limits and advantages.

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HydroSat: geometric quantities of the global water cycle from geodetic satellites

Cited by 18 publications

References 94 publications

Remote Sensing-Based Extension of GRDC Discharge Time Series - A Monthly Product with Uncertainty Estimates

Remote Sensing-Based Extension of GRDC Discharge Time Series - A Monthly Product with Uncertainty Estimates

AltiMaP: Altimetry Mapping Procedure for Hydrography Data

Water Resources in Africa: The Role of Earth Observation Data and Hydrodynamic Modeling to Derive River Discharge

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