A Compact and Broadband Four-Way Dual Polarization Waveguide Power Divider for Antenna Arrays

A Compact and Broadband Four-Way Dual Polarization Waveguide Power Divider for Antenna Arrays

The design and optimization of a novel compact and highly efficient power divider exhibiting dual-polarization in an in-phase 2 \times 4 scheme (4-way) is presented. The two fundamental orthogonal modes TE _{10} and TE _{01} arrive in-phase on each of the four square waveguides for each polarization...

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Bibliographic Details
Published in:2020 14th European Conference on Antennas and Propagation (EuCAP) pp. 1 - 5
Main Authors: Stoumpos, Charalampos, Fraysse, Jean-Philippe, Tubau, Segolene, Goussetis, George, Sauleau, Ronan, Legay, Herve
Format: Conference Proceeding
Language:English
Published: EurAAP 01-03-2020
Subjects:
dual-polarization
horn antenna array
Horn antennas
orthomode transducer
Power dividers
Satellites
Sensitivity analysis
Topology
Transducers
turnstile junction
Waveguide junctions
Waveguide power-divider
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Summary:The design and optimization of a novel compact and highly efficient power divider exhibiting dual-polarization in an in-phase 2 \times 4 scheme (4-way) is presented. The two fundamental orthogonal modes TE _{10} and TE _{01} arrive in-phase on each of the four square waveguides for each polarization by the utilization of four 3-port turnstile junctions accompanied by four E-plane and two H-plane power division structures. The power divider ends up to two commercial waveguide (WR75) ports (each for one polarization). The presented passive component can be used as a dual-polarized feeding network for a 2 \times 2 antenna array or any four-port radiating element with square input waveguides and aperture sizes above 2.4 \lambda that are commonly targeted for focal array or direct radiating elements at GEO applications. The power divider is fully metallic, a fact that makes it an ideal candidate for satellite applications. The design band is Ku-Tx (10.7-12.75 GHz), presenting a Return Loss better than 20 dB and an input-output isolation of the orthogonal modes better than 30 dB. The exciter is also subjected to sensitivity analysis for estimating its manufacturing tolerances, exhibiting a robust behavior to dimensional variations, while its losses are also evaluated around 0.1 dB when aluminum parts are assumed. Finally, a compact topology of a 2.5 \lambda aperture size array in a 2 \times 2 scheme was designed and optimized where the level of aperture efficiency was the principal design goal. The array is after connected to the exciter to obtain the final feed system.
DOI:10.23919/EuCAP48036.2020.9135912