Abstract
With the increase in the use of small uncrewed aircraft systems (UAS) there is a growing need for real-time weather forecasting to improve the safety of low-altitude aircraft operations. This will require integration of measurements with autonomous systems since current available sampling lack sufficient resolution within the atmospheric boundary layer (ABL). Thus, the current work aims to assess the ability to measure wind speeds from a quad-copter UAS and compare the performance with that of a fixed mast. Two laboratory tests were initially performed to assess the spatial variation in the vertically induced flow from the rotors. The horizontal distribution above the rotors was examined in a water tunnel at speeds and rotation rates to simulate nominally full throttle with a relative air speed of 0 or 8 m/s. These results showed that the sensor should be placed between rotor pairs. The vertical distribution was examined from a single rotor test in a large chamber, which suggested that at full throttle the sensor should be about 400 mm above the rotor plane. Field testing was then performed with the sensor positioned in between both pairs of rotors at 406, 508, and 610 mm above the rotor plane. The mean velocity over the given period was within 5.5% of the that measured from a fixed mast over the same period. The variation between the UAS and mast sensors were better correlated with the local mean shear than separation distance, which suggests height mismatch could be the source of error. The fluctuating velocity was quantified with the comparison of higher order statistics as well as the power spectral density, which the mast and UAS spectra were in good agreement regardless of the separation distance. This implies that for the current configuration a separation distance of 5.3 rotor diameters was sufficient to minimize the influence of the rotors.
Highlights
As the amount of small uncrewed aircraft systems (UAS) increases, better real-time weather forecasting in the lower atmosphere is needed
Fixed wing UAS allow for long duration flights that enable sampling over large areas, but the UAS dynamics limits its mobility and requires larger unobstructed space [15]
It should be noted that the particle image velocimetry (PIV) measurements at 0.5 m/s matched the established tunnel performance within measurement uncertainty for nearly every case
Summary
As the amount of small uncrewed aircraft systems (UAS) increases, better real-time weather forecasting in the lower atmosphere is needed. One way to improve these forecasts is to acquire accurate in situ data with high spatiotemporal resolution This is what a UAS excels at, and these more accurate forecasts can be used in real-time weather prediction to aid in improving the safety and efficiency of low-altitude aircraft operations. The progression was to use weather balloons, which work extremely well at acquiring vertical profiles of the atmosphere, typically using radiosondes. A method used to bypass this limitation is the use of tethered balloons These tethers allow for controlled height and the ability to go up and down multiple times [2–4]. Multi-rotor UAS, like the example shown, excel in the areas where the fixed wings are limited.
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