Modeling and Migration of 2-D Georadar Data: A Stationary Phase Approach

Author

Greenhalgh, Stewart A. ; Marescot, Laurent

Author_Institution

Dept. of Phys., Adelaide Univ., SA

Volume

44

Issue

9

fYear

2006

Firstpage

2421

Lastpage

2429

Abstract

This paper presents the basic kinematic and dynamic imaging and migration equations for zero-offset two-dimensional georadar profiling. The kinematic equations are derived from simple considerations of spatial impulse responses and a generating function. The dynamic equations follow from a multidimensional stationary phase approximation to the infinite spectral integrals. They show how the radar signal (amplitude and phase) depends on the shape and curvature of the reflector. The imaging equations are evaluated for the special cases of a point scatterer, a continuous reflector, and a terminating reflector. A general formula is developed by which to migrate an arbitrary shaped event of variable amplitude on the georadar section

Keywords

geophysical techniques; ground penetrating radar; remote sensing by radar; 2D georadar data; continuous reflector; dynamic imaging; generating function; georadar section; imaging equations; infinite spectral integrals; kinematic imaging; migration equations; multidimensional stationary phase approximation; point scatterer; spatial impulse responses; stationary phase approach; terminating reflector; zero-offset 2D georadar profiling; Data acquisition; Geology; Geophysics; Ground penetrating radar; Integral equations; Kinematics; Multidimensional systems; Radar imaging; Reflection; Surface cracks; Georadar; migration; modeling; stationary phase approximation;

fLanguage

English

Journal_Title

Geoscience and Remote Sensing, IEEE Transactions on

Publisher

ieee

ISSN

0196-2892

Type

jour

DOI

10.1109/TGRS.2006.875363

Filename

1677751