Scattering Studies for Two-Dimensional Exponential Correlation Textured Rough Surfaces Using Small-Slope Approximation Method

Two-dimensional exponential correlation rough surfaces characterized by textures are combined with the small-slope approximation (SSA) method to comparatively study electromagnetic (EM) scattering features of textured surfaces. The normalized copolarized radar cross section from 2-D exponential corr...

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Bibliographic Details
Published in:IEEE transactions on geoscience and remote sensing 2014-09, Vol.52 (9), p.5364-5373
Main Authors: Wei, Peng-Bo, Zhang, Min, Sun, Rong-Qing, Yuan, Xiao-Feng
Format: Article
Language:English
Subjects:
Amplitude distribution
Correlation
Correlation analysis
exponential correlation
Mathematical analysis
Mathematical models
Probability distribution
Remote sensing
Rough surfaces
Scattering
Sea surface
Simulation
small-slope approximate (SSA)
Surface layer
Surface roughness
Surface texture
Surface waves
Texture
textured surfaces
zero memory nonlinear transformation (ZMNL)
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Summary:Two-dimensional exponential correlation rough surfaces characterized by textures are combined with the small-slope approximation (SSA) method to comparatively study electromagnetic (EM) scattering features of textured surfaces. The normalized copolarized radar cross section from 2-D exponential correlation rough surfaces characterized by stripe texture and block texture, respectively, is analyzed. Several numerical results show the effects of incident angle, texture angle, correlation length, and root-mean-square height on the copolarimetric scattering from the textured rough surface. The validity of the SSA method is verified by comparisons of theoretical value and measured data. Moreover, normalized amplitude distributions of backscattering fields from cells in a scene are studied through its statistical distribution and space correlation function, which are particularly useful for analysis and simulation of remote sensing images. Finally, based on the statistical distribution and space correlation function, the zero memory nonlinear transformation method is utilized to simulate EM scattering from very large scenes. The simulated scene coincides with the original one quite well.
ISSN:0196-2892
1558-0644
DOI:10.1109/TGRS.2013.2288278