2018
DOI: 10.1186/s40645-018-0187-4
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Vertical structure of the lower troposphere derived from MU radar, unmanned aerial vehicle, and balloon measurements during ShUREX 2015

Abstract: The ShUREX (Shigaraki UAV Radar Experiment) 2015 campaign carried out at the Shigaraki Middle and Upper atmosphere (MU) observatory (Japan) in June 2015 provided a unique opportunity to compare vertical profiles of atmospheric parameters estimated from unmanned aerial vehicle (UAV), balloon, and radar data in the lower troposphere. The present work is intended primarily as a demonstration of the potential offered by combination of these three instruments for studying the small-scale structure and dynamics in t… Show more

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Cited by 9 publications
(7 citation statements)
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“…(4) has a great advantage, since shear-broadening effects are null or negligible when using a vertical beam. Even though the theoretical effects due to shear-broadening when using data collected at oblique incidences are well-established, the corrections remain challenging in practice, because they require accurate estimates of wind shears, and the wind shear profiles estimated at the radar range resolution may not be representative of shear profiles at higher resolutions (e.g., Figure 5 of Luce et al 2018). The use of data at vertical incidence will be justified a posteriori in "Comparisons between ε U and ε from the radar models" section.…”
Section: Practical Methods From Radar Datamentioning
confidence: 99%
“…(4) has a great advantage, since shear-broadening effects are null or negligible when using a vertical beam. Even though the theoretical effects due to shear-broadening when using data collected at oblique incidences are well-established, the corrections remain challenging in practice, because they require accurate estimates of wind shears, and the wind shear profiles estimated at the radar range resolution may not be representative of shear profiles at higher resolutions (e.g., Figure 5 of Luce et al 2018). The use of data at vertical incidence will be justified a posteriori in "Comparisons between ε U and ε from the radar models" section.…”
Section: Practical Methods From Radar Datamentioning
confidence: 99%
“…Therefore, all three instruments detected the same prominent temperature and humidity gradients, down to decameter scales in stratified conditions. These gradients extended horizontally over a few kilometers at least and persisted for hours without significant changes [see Luce et al (2018) Therefore, Re b is, in strict terms, not the turbulence Reynolds number but more appropriately is a measure of the broadness of the ISR. For turbulence to be well established, R must have a value of at least 2, and therefore Re b must be above 35.…”
Section: Shurex 2016 Observationsmentioning
confidence: 99%
“…
The WPR-LQ-7 is a UHF (1.3575 GHz) wind profiler radar used for routine measurements of the lower troposphere 10 at Shigaraki MU observatory (34.85°N, 136.10°E, Japan) at a vertical resolution of 100 m and a time resolution of 10 min.Following studies carried out with the 46.5 MHz Middle and Upper atmosphere (MU) radar (Luce et al, 2018), we tested models used to estimate turbulence kinetic energy (TKE) dissipation rates 𝜀 from the Doppler spectral width in the altitude range ~0.7 to 4.0 km ASL. For this purpose, we compared LQ-7-derived 𝜀 by using processed data available on line (http://www.rish.kyoto-u.ac.jp/radar-group/blr/shigaraki/data/) with direct estimates of 𝜀 (𝜀 𝑈 ) from DataHawk UAVs.
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mentioning
confidence: 99%
“…Following studies carried out with the 46.5 MHz Middle and Upper atmosphere (MU) radar (Luce et al, 2018), we tested models used to estimate turbulence kinetic energy (TKE) dissipation rates 𝜀 from the Doppler spectral width in the altitude range ~0.7 to 4.0 km ASL. For this purpose, we compared LQ-7-derived 𝜀 by using processed data available on line (http://www.rish.kyoto-u.ac.jp/radar-group/blr/shigaraki/data/) with direct estimates of 𝜀 (𝜀 𝑈 ) from DataHawk UAVs.…”
mentioning
confidence: 99%