A framework for estimating global river discharge from the Surface Water and Ocean Topography satellite mission

Michael Durand; Colin Gleason; Tamlin Pavelsky; Renato Frasson; Michael Turmon; Cedric H. David; Elizabeth Altenau; Nikki Tebaldi; Kevin Larnier; Jerome Monnier; Pierre Olivier Malaterre; Hind Oubanas; George Allen; Brian Astifan; Craig Brinkerhoff; Paul Bates; David M. Bjerklie; Stephen Coss; Robert W. Dudley; Luciana Fengolio; Pierre-Andre Garambois; Augusto Getirana; Peirong Lin; Steven A. Margulis; Pascal Matte; J.Toby Minear; Aggrey Muhebwa; Ming Pan; Daniel L. Peters; Ryan Riggs; Md Safat Sikder; Travis Simmons; Cassie Stuurman; Jay Taneja; Angelica Tarpanelli; Kerstin Schulze; Mohammad Tourian; Jida Wang

doi:10.1029/2021WR031614

A framework for estimating global river discharge from the Surface Water and Ocean Topography satellite mission

Water Resources Research

By: Michael Durand, Colin Gleason, Tamlin Pavelsky, Renato Frasson, Michael Turmon, Cedric H. David, Elizabeth Altenau, Nikki Tebaldi, Kevin Larnier, Jerome Monnier, Pierre Olivier Malaterre, Hind Oubanas, George Allen, Brian Astifan, Craig Brinkerhoff, Paul Bates, David M. Bjerklie, Stephen Coss, Robert W. Dudley, Luciana Fengolio, Pierre-Andre Garambois, Augusto Getirana, Peirong Lin, Steven A. Margulis, Pascal Matte, J.Toby Minear, Aggrey Muhebwa, Ming Pan, Daniel L. Peters, Ryan Riggs, Md Safat Sikder, Travis Simmons, Cassie Stuurman, Jay Taneja, Angelica Tarpanelli, Kerstin Schulze, Mohammad Tourian, and Jida Wang

https://doi.org/10.1029/2021WR031614

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Abstract

The Surface Water and Ocean Topography (SWOT) mission will vastly expand measurements of global rivers, providing critical new data sets for both gaged and ungaged basins. SWOT discharge products (available approximately 1 year after launch) will provide discharge for all river that reaches wider than 100 m. In this paper, we describe how SWOT discharge produced and archived by the US and French space agencies will be computed from measurements of river water surface elevation, width, and slope and ancillary data, along with expected discharge accuracy. We present for the first time a complete estimate of the SWOT discharge uncertainty budget, with separate terms for random (standard error) and systematic (bias) uncertainty components in river discharge time series. We expect that discharge uncertainty will be less than 30% for two-thirds of global reaches and will be dominated by bias. Separate river discharge estimates will combine both SWOT and in situ data; these “gage-constrained” discharge estimates can be expected to have lower systematic uncertainty. Temporal variations in river discharge time series will be dominated by random error and are expected to be estimated within 15% for nearly all reaches, allowing accurate inference of event flow dynamics globally, including in ungaged basins. We believe this level of accuracy lays the groundwork for SWOT to enable breakthroughs in global hydrologic science.

Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	A framework for estimating global river discharge from the Surface Water and Ocean Topography satellite mission
Series title	Water Resources Research
DOI	10.1029/2021WR031614
Volume	59
Issue	4
Year Published	2023
Language	English
Publisher	American Geophysical Union
Contributing office(s)	New England Water Science Center
Description	e2021WR031614, 31 p.
Google Analytic Metrics	Metrics page