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IEEE Transactions on Antennas and Propagation
Volume 46 Number 1, January 1998

Table of Contents for this issue

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95-GHz Scattering by Terrain at Near-Grazing Incidence

Fawwaz T. Ulaby, Fellow, IEEE, Adib Nashashibi, Member, IEEE, Alaa El-Rouby, Eric S. Li, Roger D. De Roo, Member, IEEE, Kamal Sarabandi, Senior Member, IEEE, Ronald J. Wellman, and H. Bruce Wallace

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Abstract:

This study, consisting of three complimentary topics, examines of the millimeter-wave backscattering behavior of terrain at incidence angles extending between 70 and 90^irc, corresponding to grazing angles of 20^irc to 0^irc. The first topic addresses the character of the statistical variability of the radar backscattering cross section per unit area \sigma_A. Based on an evaluation of an extensive data set acquired at 95 GHz, it was determined that the Rayleigh fading model (which predicts that \sigma_A is exponentially distributed) provides an excellent fit to the measured data for various types of terrain covers, including bare surfaces, grasses, trees, dry snow, and wet snow. The second topic relates to the angular variability and dynamic range of the backscattering coefficient \sigma^0, particularly near grazing incidence. In this paper, we provide a summary of data reported to date for each of several types of terrain covers. The last topic focuses on bare surfaces. A semi-empirical model for \sigma^0 is presented for vertical (VV), horizontal (HH), and cross (HV) polarizations. The model parameters include the incidence angle \theta, the surface relative dielectric constant \epsilon, and the surface roughness ks, where k = 2 \pi/\lambda and s is the surface root mean square (rms) height.

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