Editorial Type:
Article
Article Type:
Research Article

Direct Observations of Coherent Backscatter of Radar Waves in Precipitation

A. R. Jameson RJH Scientific, Inc., El Cajon, California

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A. B. Kostinski Michigan Technological University, Houghton, Michigan

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Print Publication:
01 Sep 2010
DOI:
https://doi.org/10.1175/2010JAS3488.1
Page(s):
3000–3005
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Abstract

In previous work, it was argued that a source of radar coherent scatter occurs in the direction perpendicular to the direction of wave propagation because of the presence of grids of enhanced particle concentrations with spatial periodicities in resonance with the radar wavelength. While convincing, the evidence thus far has been indirect. In this work the authors now present direct observations of radar coherent backscattered signals in precipitation in the direction of wave propagation.

The theory is developed for the cross-correlation function of the complex amplitudes in the direction of propagation calculated for nearest neighbor range bins. Data are analyzed in snow and in rain. The results agree with the earlier conclusions in the previous work, namely that coherent scatter occurs in both rain and snow, that it is larger in snow than it is in rain, and that it can be significant at times.

Corresponding author address: A. R. Jameson, 5625 N. 32nd Street, Arlington, VA 22207–1560. Email: arjatrjhsci@verizon.net

Abstract

In previous work, it was argued that a source of radar coherent scatter occurs in the direction perpendicular to the direction of wave propagation because of the presence of grids of enhanced particle concentrations with spatial periodicities in resonance with the radar wavelength. While convincing, the evidence thus far has been indirect. In this work the authors now present direct observations of radar coherent backscattered signals in precipitation in the direction of wave propagation.

The theory is developed for the cross-correlation function of the complex amplitudes in the direction of propagation calculated for nearest neighbor range bins. Data are analyzed in snow and in rain. The results agree with the earlier conclusions in the previous work, namely that coherent scatter occurs in both rain and snow, that it is larger in snow than it is in rain, and that it can be significant at times.

Corresponding author address: A. R. Jameson, 5625 N. 32nd Street, Arlington, VA 22207–1560. Email: arjatrjhsci@verizon.net

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