Title :
A scattering model for snow-covered sea ice
Author :
Tjuatja, Saibun ; Fung, Adrian K. ; Bredow, Jonathan
Author_Institution :
Wave Scattering Res. Center, Texas Univ., Arlington, TX, USA
fDate :
7/1/1992 12:00:00 AM
Abstract :
The special properties of a robust radiative transfer model for scattering from layers of inhomogeneous rough-boundary slabs are presented. The model is applied to backscattering from saline and desalinated ice. Comparisons are made at single and multiple frequencies with some of the most complete sets of measurement data available, using measured physical and electrical characteristics of the ice as inputs to the model where possible. The results show close agreement. For example, for the saline ice backscatter data set, which consisted of measurements at two like and two cross polarizations at 5 and 13.9 GHz, the agreement with model predictions is within 2 dB except at 13.9-GHz cross polarization. Backscattering from >15-cm-thick saline ice is generally dominated by scattering from the top surface while backscattering from <8-cm-thick saline ice can be strongly influenced by returns from the ice/water interface, particularly at frequencies less than about 5 GHz
Keywords :
backscatter; oceanographic techniques; remote sensing by radar; sea ice; snow; 13.9 GHz; 5 GHz; backscatter; backscattering; desalinated ice; geophysical measurement; inhomogeneous rough-boundary slabs; microwave reflection; ocean; polarimetry; polarization; radar; remote sensing; robust radiative transfer model; saline; scattering model; snow-covered sea ice; technique; Backscatter; Desalination; Electric variables measurement; Frequency measurement; Polarization; Robustness; Scattering; Sea ice; Sea measurements; Slabs;
Journal_Title :
Geoscience and Remote Sensing, IEEE Transactions on
