Title :
A technique for three-dimensional dosimetry and scattering computation of vector electromagnetic fields
Author :
Guo, Theodore C. ; Guo, Wendy W. ; Oguz, Hasan N.
Author_Institution :
Potomac Research Inc., MD, USA
fDate :
3/1/1993 12:00:00 AM
Abstract :
A dosimetry and scattering matrix formulation for the computation of vector electromagnetic fields (VEMFs) inside and outside arbitrary 3-D dielectric objects is presented. It is based on a moment method extended to vector fields. The integral equations for the VEMFs are first converted to matrix equations, and then the Green´s function within each digitized cell is derived analytically by integrating over the cell. The matrix formulation provides a fast and accurate method for dosimetry and near- or far-field computation anywhere inside or outside a 3-D object with any distribution of dielectric permittivity and electric conductivity, both of which may be complex numbers, and for any form of incident field. Comparison with the Mie formula for uniform dielectric spheres shows that the matrix method yields an accuracy of about 99.9% for a sphere discretized to 179 cells
Keywords :
Green´s function methods; S-matrix theory; dosimetry; electromagnetic field theory; electromagnetic wave scattering; vectors; 3D dielectric objects; Green function; electrical conductivity distribution; far-field computation; integral equations; matrix equations; moment method; near field computation; permittivity distribution; scattering matrix formulation; three-dimensional dosimetry; uniform dielectric spheres; vector EM field scattering; vector electromagnetic fields; Dielectrics; Distributed computing; Dosimetry; Electromagnetic fields; Electromagnetic scattering; Green´s function methods; Integral equations; Matrix converters; Mie scattering; Moment methods;
Journal_Title :
Magnetics, IEEE Transactions on
