Your search keyword '"ANTENNA RADIATION FIELD"' showing total 4 results

1. Investigation of spherical and cylindrical Luneburg lens antennas by the Green's function method

Author

Sergey Shabunin, Alexey Korotkov, Sergey Knyazev, and Boris Panchenko

Subjects

Engineering, SLOT ANTENNAS, Field (physics), Aperture, Physics::Optics, SPHERICAL LUNEBURG LENS, ANTENNA RADIATION FIELD, symbols.namesake, Optics, Electric field, STRUCTURAL OPTIMIZATION, ANTENNA RADIATION, ELECTRIC FIELD COMPONENTS, LAYERED STRUCTURES, DIRECTIONAL PATTERNS (ANTENNA), business.industry, HFSS, LENS ANTENNAS, CROSS-POLARIZED FIELDS, Luneburg lens, CIRCULAR POLARIZED, ANTENNA STRUCTURES, ELECTRIC FIELDS, SPHERES, Dipole, CYLINDRICAL ANTENNAS, APERTURE ANTENNAS, Green's function, symbols, Antenna (radio), business

Abstract

Luneburg lens antenna radiation fields are calculated with Green's functions of spherical and cylindrical layered structures. Electric field components of spherical and cylindrical Luneburg lenses excited by linear and circular polarized incident field are analysed. Dipole, slot and aperture antennas are described by electric and magnetic extraneous currents. Radiation patterns of cylindrical and spherical Luneburg lens are analysed. Co-polarized and cross-polarized field radiation patterns are shown. The proposed method significantly reduces the computing time for multi-layered lenses in comparison with the most commonly used in antenna design. The first step antenna structure optimization may be performed for a shorter time. The results may be used as the first approximation for Ansys HFSS and other software.

Published

2016

2. Investigation of spherical and cylindrical Luneburg lens antennas by the Green's function method

Author

Knyazev, S., Korotkov, A., Panchenko, B., Shabunin, S., Knyazev, S., Korotkov, A., Panchenko, B., and Shabunin, S.

Abstract

Luneburg lens antenna radiation fields are calculated with Green's functions of spherical and cylindrical layered structures. Electric field components of spherical and cylindrical Luneburg lenses excited by linear and circular polarized incident field are analysed. Dipole, slot and aperture antennas are described by electric and magnetic extraneous currents. Radiation patterns of cylindrical and spherical Luneburg lens are analysed. Co-polarized and cross-polarized field radiation patterns are shown. The proposed method significantly reduces the computing time for multi-layered lenses in comparison with the most commonly used in antenna design. The first step antenna structure optimization may be performed for a shorter time. The results may be used as the first approximation for Ansys HFSS and other software.

Published

2016

3. Investigation of spherical and cylindrical Luneburg lens antennas by Green's function method

Author

Alexey Korotkov, Boris Panchenko, Sergey Knyazev, and Sergey Shabunin

Subjects

ANTENNA DESIGN, GREEN'S FUNCTION, Physics::Optics, GREEN'S FUNCTION METHODS, ANTENNA RADIATION FIELD, Astrophysics::Cosmology and Extragalactic Astrophysics, LENSES, MAGNETIC MULTILAYERS, Radiation pattern, law.invention, Optics, law, Dipole antenna, ANTENNA RADIATION, ELECTRIC FIELD COMPONENTS, Computer Science::Information Theory, Physics, DIRECTIONAL PATTERNS (ANTENNA), LAYERED STRUCTURES, Coaxial antenna, business.industry, CROSS-POLARIZED FIELDS, LENS ANTENNAS, Antenna aperture, Antenna measurement, Antenna factor, Luneburg lens, POLARIZATION LOSS, ELECTRIC FIELDS, Lens (optics), CYLINDRICAL ANTENNAS, APERTURE ANTENNAS, DIPOLE ANTENNAS, business, CIRCULAR POLARIZED ANTENNAS, ANTENNA RADIATION PATTERNS

Abstract

Luneburg lens antenna radiation fields are calculated with Green's functions of spherical and cylindrical layered structures. Electric field components for Luneburg lenses excited by a linear and circular polarized antenna are analyzed. Co-polarized and cross-polarized field radiation patterns are shown. Reflection from the lens, losses in the lens material, spillover and polarization loss are taken into account for antenna gain calculation. The proposed method significantly reduces computing time for multilayered lens in comparison with the most commonly used in antenna design. © 2015 Radio Society (Mauritius).

Published

2015

4. Investigation of spherical and cylindrical Luneburg lens antennas by Green's function method

Author

Knyazev, S., Korotkov, A., Panchenko, B., Shabunin, S., Knyazev, S., Korotkov, A., Panchenko, B., and Shabunin, S.

Abstract

Luneburg lens antenna radiation fields are calculated with Green's functions of spherical and cylindrical layered structures. Electric field components for Luneburg lenses excited by a linear and circular polarized antenna are analyzed. Co-polarized and cross-polarized field radiation patterns are shown. Reflection from the lens, losses in the lens material, spillover and polarization loss are taken into account for antenna gain calculation. The proposed method significantly reduces computing time for multilayered lens in comparison with the most commonly used in antenna design. © 2015 Radio Society (Mauritius).

Published

2015