Estimating water discharge from large radar altimetry datasets

Getirana, Augusto; Peters‐Lidard, Christa D.

doi:10.5194/hess-17-923-2013

Cited by 58 publications

(36 citation statements)

References 25 publications

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“…This technique have been successfully applied to estimate river discharge using altimetry-based water levels when it was possible to derive the rating curve a common period of observation. It permits to derive river discharge with accuracy better than 20% (e.g., [18][19][20]22,[46][47][48]).…”

Section: Discharge Estimatesmentioning

confidence: 99%

Monitoring Water Levels and Discharges Using Radar Altimetry in an Ungauged River Basin: The Case of the Ogooué

et al. 2018

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Radar altimetry is now commonly used for the monitoring of water levels in large river basins. In this study, an altimetry-based network of virtual stations was defined in the quasi ungauged Ogooué river basin, located in Gabon, Central Africa, using data from seven altimetry missions (Jason-2 and 3, ERS-2, ENVISAT, Cryosat-2, SARAL, Sentinel-3A) from 1995 to 2017. The performance of the five latter altimetry missions to retrieve water stages and discharges was assessed through comparisons against gauge station records. All missions exhibited a good agreement with gauge records, but the most recent missions showed an increase of data availability (only 6 virtual stations (VS) with ERS-2 compared to 16 VS for ENVISAT and SARAL) and accuracy (RMSE lower than 1.05, 0.48 and 0.33 and R 2 higher than 0.55, 0.83 and 0.91 for ERS-2, ENVISAT and SARAL respectively). The concept of VS is extended to the case of drifting orbits using the data from Cryosat-2 in several close locations. Good agreement was also found with the gauge station in Lambaréné (RMSE = 0.25 m and R 2 = 0.96). Very good results were obtained using only one year and a half of Sentinel-3 data (RMSE < 0.41 m and R 2 > 0.89). The combination of data from all the radar altimetry missions near Lamabréné resulted in a long-term (May 1995 to August 2017) and significantly improved water-level time series (R 2 = 0.96 and RMSE = 0.38 m). The increase in data sampling in the river basin leads to a better water level peak to peak characterization and hence to a more accurate annual discharge over the common observation period with only a 1.4 m 3 •s −1 difference (i.e., 0.03%) between the altimetry-based and the in situ mean annual discharge.

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Section: Discharge Estimatesmentioning

confidence: 99%

Monitoring Water Levels and Discharges Using Radar Altimetry in an Ungauged River Basin: The Case of the Ogooué

et al. 2018

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“…Conventionally, discharge measurements of rivers without an established gauging station can be conducted using current metres (i.e. mechanical devices such as impellers or rotating cups; Rantz, 1982), acoustic Doppler velocimeters (Muste et al, 2007), acoustic Doppler current profilers (Gordon, 1989;Oberg and Mueller, 2007;Simpson, 2001;Yorke and Oberg, 2002), remote sensing methods (Birkinshaw et al, 2014;Costa et al, 2006;Getirana and Peters-Lidard, 2013) or estimation by postevent dendrogeomorphic evidence analysis (Ballesteros Cánovas et al, 2011;Ruiz-Villanueva et al, 2010). It is, however, not only time consuming and labour intensive, but also unsafe and technically difficult to extend intrusive techniques to conduct field measurements during high flow events.…”

Section: Introductionmentioning

confidence: 99%

Application of an automated LSPIV system in a mountainous stream for continuous flood flow measurements

Qian

Tang

et al. 2016

Hydrological Processes

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Abstract:An imaging-based automated large-scale particle image velocimetry (LSPIV) system for flash flood monitoring is developed and deployed in a mountainous stream in the Longchi Catchment, Chengdu, China. This system is built from a low-cost Raspberry Pi board-level computer with a camera module, which can acquire continuous images/videos automatically at programmed intervals. The minimum quadratic difference algorithm tracks surface patterns as flow tracers to estimate the distribution of surface velocities. Meanwhile, a stereo imaging-based 'virtual pole' method has been developed to reconstruct the threedimensional topography with a stereo digital camera, and a cross-sectional bathymetry has been generated without manual surveying. The varying water stage and water surface gradient, which are critical parameters that affect image rectification and surface velocity measurements, can also be directly resolved by applying the two imaging modules together. Discharge can then be estimated with the velocity-area method through selected cross sections. A flash flood that occurred between 24 July 2014 and 25 July 2014 is selected for analysis. The water surface level reconstructed from image processing was validated with marked water levels, and a good agreement was found with a root mean square error of 3.7 cm. The discharge recorded during the flood recession process ranged from approximately 3.5 to 27 m 3 /s. The rating curve obtained can be well described by a power function, and the linear regression suggested a Manning's n roughness coefficient of 0.18 of one specific cross section. Some limitations of the presented large-scale particle image velocimetry system are also put forward, and possible solutions are provided for future improvements. With these proposed upgrades, the system can provide valuable datasets of flash floods in steep mountainous streams, which are critically needed for improving our understanding and modelling of many hydrological processes associated with flood generation, propagation and erosion, as well as for real-time forecasting.

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“…Getirana et al . [2009] and Getirana and Peters‐Lidard [] developed rating curves based on altimetric level measurements and modeled discharge from a hydrological model and a routing scheme, respectively, in order to estimate river discharge.…”

Section: Introductionmentioning

confidence: 99%

Assimilation of radar altimetry to a routing model of the Brahmaputra River

Michailovsky

Milzow

Bauer‐Gottwein

2013

Water Resources Research

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[1] While satellite-based remote sensing has provided hydrologists with valuable new data sets, integration of such data sets in operational modeling systems is usually not straightforward due to spatial or temporal resolution issues or because remote sensing does not directly measure the hydrological quantities of interest. This is the case for satellitebased radar altimetry. River-level variations can be tracked using radar altimetry at a temporal resolution between 10 and 35 days, depending on the satellite, but hydrologists are typically interested in river flows rather than levels and require predictions at daily or even subdaily temporal resolutions. One way to exploit satellite radar altimetry is therefore to combine the data with hydrological models in a data assimilation framework. In this study, radar altimetry data from six ENVISAT virtual stations were assimilated to a routing model of the main reach of the Brahmaputra River driven by the outputs of a calibrated rainfall runoff model. The extended Kalman filter was used to update the routed water volumes for the years 2008-2010. Model performance was improved with the Nash-Sutcliffe model efficiency for daily discharge increasing from 0.78 to 0.84. The method uses very little in situ data and is easily implemented as an add-on to hydrological models, and it therefore has the potential for large-scale application to improve hydrological predictions in many river basins.Citation: Michailovsky, C. I., C. Milzow, and P. Bauer-Gottwein (2013), Assimilation of radar altimetry to a routing model of the Brahmaputra River, Water Resour. Res., 49,[4807][4808][4809][4810][4811][4812][4813][4814][4815][4816]

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Estimating water discharge from large radar altimetry datasets

Cited by 58 publications

References 25 publications

Monitoring Water Levels and Discharges Using Radar Altimetry in an Ungauged River Basin: The Case of the Ogooué

Monitoring Water Levels and Discharges Using Radar Altimetry in an Ungauged River Basin: The Case of the Ogooué

Application of an automated LSPIV system in a mountainous stream for continuous flood flow measurements

Assimilation of radar altimetry to a routing model of the Brahmaputra River

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