2020
DOI: 10.3390/rs12203317
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QCam: sUAS-Based Doppler Radar for Measuring River Discharge

Abstract: The U.S. Geological Survey is actively investigating remote sensing of surface velocity and river discharge (discharge) from satellite-, high altitude-, small, unmanned aircraft systems- (sUAS or drone), and permanent (fixed) deployments. This initiative is important in ungaged basins and river reaches that lack the infrastructure to deploy conventional streamgaging equipment. By coupling alternative discharge algorithms with sensors capable of measuring surface velocity, streamgage networks can be established… Show more

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Cited by 33 publications
(34 citation statements)
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“…The system, termed by the authors as RAPTOR-UAV, enabled to capture large-scale, nonstationary regions of the velocity field where the flow fields are persistent and chaotic. Recently, remote sensing of surface velocity and river discharge has been addressed in [92] through UAS-based doppler radars yielding results comparable to conventional streamgaging if cross-sectional area is available.…”
Section: Surface Velocity and Flow Estimationsmentioning
confidence: 99%
“…The system, termed by the authors as RAPTOR-UAV, enabled to capture large-scale, nonstationary regions of the velocity field where the flow fields are persistent and chaotic. Recently, remote sensing of surface velocity and river discharge has been addressed in [92] through UAS-based doppler radars yielding results comparable to conventional streamgaging if cross-sectional area is available.…”
Section: Surface Velocity and Flow Estimationsmentioning
confidence: 99%
“…At a short temporal scale, river waves can be dominated by eddies and secondary currents. Thus if the sampling time of a Doppler radar was inadequate and eddies were large, the radar would measure the eddy-dominated velocities rather than the surface scatterers that are located on the surface of larger scale waves, which represent the river flow primary velocity [47]. Thus the SVR instrument has internal filters to smooth velocity measurements and cancel the effect of local eddies.…”
Section: Svrmentioning
confidence: 99%
“…In their outlook on future work, the authors discussed UAS deployment of this instrument. To date, there is only one study reporting actual UAS-deployment of a Doppler radar sensor [47], in which Fulton et al tested a continuous wave 24 GHz Doppler radar (developed by the USGS and Sommer Messtechnik) in five flights over four different rivers in the USA. UAS-borne observations were compared with another reference handheld radar and an acoustic Doppler velocimeter: differences were typically of a few cm/s when comparing the velocity value retrieved at the location of maximum velocity; however, comparisons of the horizontal velocity profile across the XS are not reported in the paper.…”
Section: Introductionmentioning
confidence: 99%
“…Therefore, more and more attention has been paid to the corresponding monitoring technologies as detection is required before proper disposal. Compared with other surveillance means such as laser and photoelectricity, radar-based systems have an insensitivity to environmental changes and strong all-day, all-weather applicability and, thus, are used in many applications [1][2][3][4] in which the feasibility for UAV detection has been shown in [5][6][7]. Unfortunately, the high radiation power from active radar aggravates the complexity of the surrounding electromagnetic environment, and its use might be limited to avoid other severe safety accidents in some sensitive areas, such as oil depots and granaries.…”
Section: Introductionmentioning
confidence: 99%