Toward global mapping of river discharge using satellite images and at-many-stations hydraulic geometry

Rivers provide critical water supply for many human societies and ecosystems, yet global knowledge of their flow rates is poor. We show that useful estimates of absolute river discharge (in cubic meters per second) may be derived solely from satellite images, with no ground-based or a priori informa...

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Veröffentlicht in:	Proceedings of the National Academy of Sciences - PNAS 2014-04, Vol.111 (13), p.4788-4791
Hauptverfasser:	Gleason, Colin J., Smith, Laurence C.
Format:	Artikel
Sprache:	eng
Schlagworte:	Artificial satellites Canada China Coefficients Conservation of Natural Resources Ecosystem studies ecosystems Feasibility Studies food security Geological Phenomena Geometry Humans Hydraulics Hydrodynamics Hydrological modeling image analysis Internationality Landsat Lotic systems Mapping Models, Theoretical Natural resource management Physical Sciences remote sensing River water Rivers Satellite Communications Satellites Surface water thematic maps United States Water water management Water Supply
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creator	Gleason, Colin J. Smith, Laurence C.
description	Rivers provide critical water supply for many human societies and ecosystems, yet global knowledge of their flow rates is poor. We show that useful estimates of absolute river discharge (in cubic meters per second) may be derived solely from satellite images, with no ground-based or a priori information whatsoever. The approach works owing to discovery of a characteristic scaling law uniquely fundamental to natural rivers, here termed a river’s at-many-stations hydraulic geometry. A first demonstration using Landsat Thematic Mapper images over three rivers in the United States, Canada, and China yields absolute discharges agreeing to within 20–30% of traditional in situ gauging station measurements and good tracking of flow changes over time. Within such accuracies, the door appears open for quantifying river resources globally with repeat imaging, both retroactively and henceforth into the future, with strong implications for water resource management, food security, ecosystem studies, flood forecasting, and geopolitics.
doi_str_mv	10.1073/pnas.1317606111
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subjects	Artificial satellites Canada China Coefficients Conservation of Natural Resources Ecosystem studies ecosystems Feasibility Studies food security Geological Phenomena Geometry Humans Hydraulics Hydrodynamics Hydrological modeling image analysis Internationality Landsat Lotic systems Mapping Models, Theoretical Natural resource management Physical Sciences remote sensing River water Rivers Satellite Communications Satellites Surface water thematic maps United States Water water management Water Supply
title	Toward global mapping of river discharge using satellite images and at-many-stations hydraulic geometry
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