A general radar equation for the bistatic acoustic sounder

Boundary-Layer Meteorol

Helmis

et al. 1983

Self Cite

In this paper, measurements of the first 150 m of the atmospheric boundary layer obtained by a high-frequency acoustic mini-sounder are compared with measurements obtained by a full complement of instruments including sonic Anemometers mounted on the Boulder Atmospheric Observatory tower. The acoustic mini-sounder, starting as low as 6 m from the ground, measures in the monostatic mode the profiles of the vertical wind speed, w, and of the temperature structure parameter, C$ with enhanced height resolution of the order of 1 m and time resolution of the order of 30 s. The results of the comparison show that the high-frequency mini-sounder is an effective atmospheric boundary-layer profiler that is also portable and relatively inexpensive.Measurements of the spectrum of Cg are presented that provide information on the local isotropy of the temperature field. Statistics of the variability of C: in both stable and unstable conditions are also given.The sounder's capabilities are further demonstrated by some detailed observations of the structure and time evolution of a thermal plume root at noon and of a nocturnal, stably stratified layer in which a dynamic instability develops. The plume starts at a height of less than 5 m, possesses substantial internal structure, and includes vertical velocities in excess of 2 m s -'.

Section: Theoretical Backgroundmentioning

confidence: 99%

Section: Theoretical Backgroundmentioning

confidence: 99%

See 1 more Smart Citation

Quantitative low-level acoustic sounding and comparison with direct measurements

Boundary-Layer Meteorol

Helmis

et al. 1983

Self Cite

“…The antenna radiation patterns for use in the radar equation were calculated from the array geometry (Moulsley et al, 1978;Moulsley and Cole, 1980).…”

Section: Methodsmentioning

confidence: 99%

“…The first two are functions of temperature, humidity and to a lesser extent pressure, and can be accurately calculated from measurements of these parameters (Sutherland, 1975) for any given frequency. Excess attenuation is the term used for loss of acoustic intensity due to refraction by the wind (Neff, 1978;Moulsley and Cole, 1980) and turbulent beam broadening (Brown and Clifford, 1976;Clifford and Brown, 1980). Refraction results in a change in the angle of arrival of the backscattered sound which gives rise to loss of received intensity due to the lower-sensitivity of the receiving antenna off-axis.…”

Section: Acoustic Soundermeasurementsmentioning

confidence: 99%

A quantitative comparison of horizontal and vertical acoustic sounding with in-situ measurements

Boundary-Layer Meteorol

Helmis

et al. 1985

Self Cite

In this paper, we present some results on an experiment to test the accuracy and utility of a horizontally-aimed acoustic sounder. A high-frequency, high-resolution mini-sounder was mounted on the mast of the Boulder Atmospheric Observatory aimed in the cross-wind direction. Measurements of C$, wind velocity and temperature and velocity variances were obtained under both stable and unstable conditions. These measurements were found to be in agreement with the equivalent values obtained, where appropriate, by the tower-fixed instrumentation and a vertically-pointed sounder, confirming the accuracy of the horizontal sounder. In addition, some information into the horizontal structure of plumes and gravity waves was obtained along with evidence of lack of excess attenuation at least for lengths within the unambiguous range of mini-sounders.

Measurement of boundary layer structure parameter profiles by acoustic sounding and comparison with direct measurements

Quart J Royal Meteoro Soc

Cole

et al. 1981

Acoustic sounder derived profiles of the atmospheric velocity and temperature structure parameters, Cv2 and CT2, are presented. the former is obtained using a novel bistatic acoustic sounder comprising a fan beam transmitter and a vertically directed receiver. Simultaneous profiles of the temperature structure parameter are obtained using a conventional monostatic sounder. Time histories of these quantities at two heights in the boundary layer are given and are compared with in‐situ measurements. the results indicate significant anisotropy in the temperature field at scales greater than a few metres and emphasize the care required when comparing directly measured and acoustically estimated turbulence quantities. the significance of anisotropy in the assessment of excess attenuation is also discussed.