Title :
Quasi-isoplanatic radiation transfer through randomly moving particles
Author_Institution :
Cooperative Inst. for Res. in Environ. Sci., Colorado Univ., Boulder, CO, USA
fDate :
12/1/1993 12:00:00 AM
Abstract :
An iterative solution of an improved forward-scattering approximation for the radiative-transfer equation is derived. The narrow-angle approximation is useful for optical and acoustic beam propagation in the ocean and the atmosphere, where particle sizes are much larger than the wavelength. The improved narrow-angle approximation is useful for a cluster of anisotropic scatterers, and when the cluster is subjected to winds or currents. The solution of the derived equation is sought in terms of uniformly convergent iteration series via the two-scale embedding technique. The lowest iterative of the technique provides an approximate solution that differs from the commonly used successive substitution technique because it takes into account some of the multiple scattering terms. An example of wave propagation through randomly moving particles, useful for remote sensing, is considered
Keywords :
acoustic wave scattering; atmospheric light propagation; convergence of numerical methods; electromagnetic wave scattering; iterative methods; light scattering; radiative transfer; remote sensing; acoustic beam propagation; atmosphere; cluster of anisotropic scatterers; forward-scattering approximation; iterative solution; light scattering; multiple scattering; narrow-angle approximation; ocean; optical beam propagation; quasi-isoplanatic radiation transfer; radiative-transfer equation; randomly moving particles; remote sensing; two-scale embedding technique; uniformly convergent iteration series; wave propagation; wind; Acoustic beams; Acoustic propagation; Acoustic scattering; Equations; Geometrical optics; Optical beams; Optical propagation; Optical scattering; Optical sensors; Particle scattering;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
