Mehmet Faruk Cengiz scite author profile

A novel circular reconfigurable metasurface (MS) based compact ultra-wideband (UWB) hybrid coupler is developed for Ku-band applications. The coupler is developed using the substrateintegrated gap waveguide (SIGW) technology. The coupler structure consists of two layers, the bottom layer represents the artificial magnetic surface of the periodic structures and the ridges in between that guide the wave in the required direction with minimum dispersion. It involves the coupling section with a centered etched slot and two additional vias to achieve the basic hybrid coupler properties. This layer is nominated as the ridge layer. The second layer is a circular shape of a dielectric gap loaded with the top ground. The top ground is left solid for a non-reconfigurable coupler. Concerning the reconfigurable coupler, this layer contains an artificial metasurface of Jerusalem cross elements where the copper is etched around. This layer is nominated as the gap layer. This MS surface is mechanically rotated to offset the magnitude and phase of the signal going to the through and coupled ports. The findings obtained from the simulations show that the reconfiguration can be accomplished by rotating the MS around the source coupler's central axis. The rotation is tested between 0°to 180°in the counter-clockwise direction. The operating frequency range of the coupler is between 11.94 to 16.91 GHz, which covers approximately the whole Ku-band. The coupler delivers continuously adjustable amplitude between 2.6 and 4.8 dB while the phase differences within 77°to 105°over a fractional bandwidth (FBW) of 34.45%. It is manufactured using PCB technology and measured using network analyzer. A strong agreement is achieved between simulations and measurements. The proposed coupler can be used in traditional beam-forming and beam-steering networks by changing the rotation angle or the operating frequency. The developed coupler can replace the Butler and Bless matrices with their complication, heavy number of phase shifters, and crossover problems. The current work can be extended to operate in the mm-Wave band by changing the dimension and the material of the unit cell of the ridge layer of the coupler. INDEX TERMS 3 dB hybrid coupler, gap waveguide, MS, tunable coupler, SIGW I. INTRODUCTIONC OUPLERS with their numerous functionalities have received great attention in the development of multistandard communication systems. The functions of signal isolation, mixing, and separation, as well as signal amplitude and phase acquisition, are vital for 5G and future 6G communication systems, making directional couplers critical components. At low-frequency bands, waveguides and microstrip couplers have achieved remarkable advancements in recent years. However, microstrip couplers encounter significant dielectric losses in the millimeter wave frequency region. In addition, standard metallic waveguide couplers suffer from difficulty in production, high costs and the ability to integrate with other networks. The operation at higher frequencies requir...

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A Novel Substrate Integrated Gap Waveguide Ultra Wide-Band Circular Directional Coupler for Ku Band Applications

Cengiz

Allam

Fawzy

2023

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