Abstract:
The feed efficiency, a first approximation to the aperture efficiency of a paraboloid or a conventional Cassegrain antenna, is used to define uniquely a combinedE- andH-p...Show MoreMetadata
Abstract:
The feed efficiency, a first approximation to the aperture efficiency of a paraboloid or a conventional Cassegrain antenna, is used to define uniquely a combinedE- andH-plane phase center of the feed pattern. A formula for numerical calculation of the combined phase center is presented, as well as theoretical results of the feed position tolerances and the efficiency loss due to differences in the principal plane phase patterns.
Published in: IEEE Transactions on Antennas and Propagation ( Volume: 31, Issue: 1, January 1983)
Keywords assist with retrieval of results and provide a means to discovering other relevant content. Learn more.
- IEEE Keywords
- Index Terms
- Resonance Frequency ,
- Unit Vector ,
- Phase Difference ,
- First Approximation ,
- Feed Conversion Ratio ,
- Circularly Polarized ,
- Radiation Pattern ,
- Eating Patterns ,
- Phase Pattern ,
- Phase Center ,
- Microstrip Antenna ,
- Eigenvalue Equation ,
- Conventional Antenna ,
- Cross-polarization Level ,
- Paraboloid ,
- Reflector Antenna ,
- Rectangular Antenna ,
- Feeding Position
Keywords assist with retrieval of results and provide a means to discovering other relevant content. Learn more.
- IEEE Keywords
- Index Terms
- Resonance Frequency ,
- Unit Vector ,
- Phase Difference ,
- First Approximation ,
- Feed Conversion Ratio ,
- Circularly Polarized ,
- Radiation Pattern ,
- Eating Patterns ,
- Phase Pattern ,
- Phase Center ,
- Microstrip Antenna ,
- Eigenvalue Equation ,
- Conventional Antenna ,
- Cross-polarization Level ,
- Paraboloid ,
- Reflector Antenna ,
- Rectangular Antenna ,
- Feeding Position
