Title :
Analysis of the iterative Kirchhoff approximation for rough surface scattering
Author_Institution :
Sch. of Electr. & Comput. Eng., Oklahoma State Univ., Stillwater, OK, USA
Abstract :
The iterative Kirchhoff approximation has been numerically applied to one-dimensionally rough, perfectly conducting statistical surfaces, and the backscattering predicted from the first and second iterations compared with the “exact” scattering found from the moment method. The VV second-iteration scattering proves accurate at all incidence angles with slightly rough surfaces and up to 85° with large-scale rough surfaces. At HH the second-iteration scattering loses accuracy at 75° with small scale rough surfaces and 50° with large-scale roughness. Scattering models based on the second-iteration IKA actually give better results at HH than would be suggested by the numerical evaluation of the IKA. The numerical results show that these models can be accurately applied to surfaces that include moderate large-scale roughness without first separating the roughness spectrum into large- and small-scale components
Keywords :
backscatter; geophysical techniques; radar cross-sections; radar polarimetry; radar theory; remote sensing by radar; terrain mapping; backscatter; backscattering; geophysical measurement technique; incidence angle; iteration; iterative Kirchhoff approximation; land surface; large-scale roughness; one-dimensionally rough surface; perfectly conducting statistical surface; polarization; radar polarimetry; radar remote sensing; radar scattering; radar theory; rough surface; terrain mapping; Backscatter; Iterative methods; Kirchhoff´s Law; Large-scale systems; Magnetic fields; Moment methods; Optical scattering; Rough surfaces; Sea surface; Surface roughness;
Conference_Titel :
Geoscience and Remote Sensing Symposium, 1999. IGARSS '99 Proceedings. IEEE 1999 International
Conference_Location :
Hamburg
Print_ISBN :
0-7803-5207-6
DOI :
10.1109/IGARSS.1999.771526
