On the Temporal Characteristics of Radar Coherent Structures in Snow and Rain

Previous work showed that the magnitudes of the radar-backscattered amplitudes have statistically significant periodic components of frequencies (f) in excess of those arising from the Doppler velocity fluctuations of incoherent scatter. Analyses in both rain and snow in the earlier work revealed wh...

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Bibliographic Details
Published in:Journal of applied meteorology and climatology 2010-09, Vol.49 (9), p.1891-1893
Main Author: Jameson, A. R.
Format: Article
Language:English
Subjects:
Amplitude
Backscatter
Backscattering
Coherent scattering
Crystals
Doppler sonar
Earth, ocean, space
Exact sciences and technology
External geophysics
Fluctuations
Fourier transforms
Frequency ranges
Ice
Ice crystals
Incoherent scattering
Meteorology
Precipitation
Radar
Radar range
Radar tracking
Rain
Scattering
Signal processing
Snow
Spectral reflectance
Statistical analysis
Structures
Studies
Sunlight
Time series
Trends
Velocity
Wavelength
Wavelengths
Wavelet transforms
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Summary:Previous work showed that the magnitudes of the radar-backscattered amplitudes have statistically significant periodic components of frequencies (f) in excess of those arising from the Doppler velocity fluctuations of incoherent scatter. Analyses in both rain and snow in the earlier work revealed what is interpreted as pervasive coherent scatter. This coherency is thought to come from precipitation structures acting like gratings in resonance with the radar wavelength that, when they move with a velocity component transverse to the beam, induce the observedf. The purpose of this article is to characterize briefly the temporal structure offand, thereby indirectly, the temporal character of the structures producing the radar coherent backscatter. It is found that these structures last considerably longer than the decorrelation times of a few to 10 milliseconds, characteristic of Doppler velocity fluctuations associated with incoherent scatter. For the data analyzed, though, most last no more than a significant fraction of 1 s. Hence, for the observed transverse velocity of 2 ms−1, the dimensions of the gratings producing the radar coherent backscatter are only on the order of tens of centimeters to a few meters. Therefore, the typically large sampling volumes of most radars will contain many of these grids at any given time. Consequently, during 1 s of observations, one can envision the coherent scatter as coming from many individual grids twinkling on and off, much like the transient spectral reflections off ice crystals falling in sunlight.
ISSN:1558-8424
1558-8432
DOI:10.1175/2010JAMC2531.1