Title :
Near-field scattering by physical theory of diffraction and shooting and bouncing rays
Author_Institution :
Dept. of Electr. Eng., Nat. Taiwan Univ., Taipei, Taiwan
fDate :
4/1/1998 12:00:00 AM
Abstract :
This paper proposes a method to compute the near-field RCS and Doppler spectrum of a target when the distances to the antennas are comparable to the target size. By dealing with a small piece of the target surface at a time, the transmitting antenna, and the receiving antenna are in the far-field zone of the small piece of the induced currents. The electromagnetic field produced by this small piece of induced currents can be written as a spherical wave. Sum up all spherical waves produced by every small piece of induced currents and we can obtain the total scattered field at the receiving antenna. The physical theory of diffraction (PTD) and the method of shooting and bouncing rays (SBR) are modified to evaluate the received signals. Numerical results based on these techniques are obtained and discussed. The formulation applies the simple concepts of “equivalent” image and vector effective height, which are believed to be novel
Keywords :
Doppler effect; antenna radiation patterns; electromagnetic fields; electromagnetic induction; electromagnetic wave scattering; physical theory of diffraction; radar cross-sections; receiving antennas; spectral analysis; transmitting antennas; Doppler spectrum; PTD; RCS; antenna distance; electromagnetic field; equivalent image; far-field zone; induced currents; near-field scattering; physical theory of diffraction; received signals; receiving antenna; shooting and bouncing rays; spherical waves; target size; target surface; total scattered field; transmitting antenna; vector effective height; Councils; Electromagnetic fields; Electromagnetic scattering; Frequency; Helium; Physical theory of diffraction; Radar cross section; Radar scattering; Receiving antennas; Transmitting antennas;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
