Low sidelobe level circularly polarised monopulse slot waveguide antenna array for Ka-band application

A circularly polarised (CP) monopulse waveguide antenna array for Ka-band wireless communication is proposed. The antenna structure can be divided into six layers from top to bottom, including radiating layer, aperture layer, cavity layer, aperture layer, feeding layer and monopulse comparator. The...

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Bibliographic Details
Published in:IET microwaves, antennas & propagation antennas & propagation, 2020-12, Vol.14 (15), p.1919-1925
Main Authors: Wang, Ankang, Li, Xi, Zhao, Jiawei, Yi, XiangJie, Yang, Lin, Zhang, Yu
Format: Article
Language:English
Subjects:
antenna feeds
antenna radiation patterns
antenna structure
aperture layer
circularly polarised antenna array
coupling layer
coupling parameters
CP monopulse applications
CP radiation pattern
difference‐pattern amplitude imbalance
efficiency 75 percent
electromagnetic wave polarisation
frequency 34.5 GHz to 35.8 GHz
horn antennas
horn radiator
Ka‐band application
Ka‐band wireless communication
low sidelobe characteristics
microstrip antenna arrays
millimetre wave antenna arrays
millimetre wave communication
monopulse comparator
monopulse radiation mode
monopulse slot waveguide antenna array
monopulse system
radiation efficiency
Research Article
sidelobe level
slot antenna arrays
sum‐pattern maximum gain
Taylor distribution
transmission modes
upper radiating layer
wireless channels
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Summary:A circularly polarised (CP) monopulse waveguide antenna array for Ka-band wireless communication is proposed. The antenna structure can be divided into six layers from top to bottom, including radiating layer, aperture layer, cavity layer, aperture layer, feeding layer and monopulse comparator. The upper radiating layer allows two transmission modes of the transverse electric (TE) wave and the transverse magnetic (TM) wave to pass through. The 90° phase difference can be obtained by adjusting the horizontal and vertical angles of the horn radiator, which realises the CP radiation pattern. Besides, the 0° or180° phase difference produced by the monopulse comparator enables the antenna to obtain a monopulse radiation mode. In order to obtain the low sidelobe characteristics, the coupling parameters of the coupling layer are weighted by the Taylor distribution. The overall size of the antenna is 194 × 25 × 31 mm3. The slot waveguide antenna is fabricated and measured to validate the proposed design. The measured results show that the monopulse system can achieve an impedance bandwidth of 3.7% (34.5–35.8 GHz) in the Ka-band at the centre frequency of 35 GHz. The sum-pattern maximum gain and radiation efficiency are 23.3 dBic and 75% at 35 GHz, and the gain of the whole bandwidth is >20 dBic. The axial ratio and the sidelobe level is less than 1.2 and −28 dB, respectively. The difference-pattern amplitude imbalance is
ISSN:1751-8725
1751-8733
DOI:10.1049/iet-map.2020.0685