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Circularly Polarized Spidron Fractal Dielectric Resonator Antenna
Altaf, Amir,Youngoo Yang,Kang-Yoon Lee,Keum Cheol Hwang IEEE 2015 IEEE antennas and wireless propagation letters Vol.14 No.-
<P>In this letter, a circularly polarized Spidron fractal dielectric resonator antenna is presented. A wide 3-dB axial ratio (AR) bandwidth is realized by merging a Spidron fractal dielectric resonator and a C-shaped slot that can produce circular polarization. The proposed antenna is excited through the coupling between a C-shaped slot in the ground plane and a 50-Ω microstrip feeding line. A prototype of the antenna is fabricated and tested. Reasonable agreement is achieved between the measurement and simulation. The experimental results show that the proposed antenna has a -10- dB reflection bandwidth of 37.29% (4.32-6.30 GHz) and a 3-dB AR bandwidth of 11.57% (5.13-5.76 GHz). The measured gain of the antenna ranges 2.20 dBic to 3.16 dBic within the AR bandwidth.</P>
Wideband Circularly Polarized Spidron Fractal Slot Antenna with an Embedded Patch
Altaf, Amir,Yang, Youngoo,Lee, Kang-Yoon,Hwang, Keum Cheol Hindawi Limited 2017 International journal of antennas and propagation Vol.2017 No.-
<P>In this communication, a wideband circularly polarized (CP) Spidron fractal microstrip antenna is proposed based on the concept of embedded structures. The proposed antenna is excited by a tapered microstrip feedline. A wide 3 dB axial ratio (AR) bandwidth of 28.81% (3.09–4.13 GHz) is obtained by merging the CP bands of the Spidron fractal slot and patch antennas. In addition, a measured −10 dB reflection bandwidth of 47.25% (2.57–4.16 GHz) is reported. The measured results are in reasonable concurrence with the simulated results. The measured gain varies between 2.12 dBic and 3.56 dBic within the AR bandwidth.</P>
A D-Band Waveguide-SIW Transition for 6G Applications
Altaf Amir,Elahi Manzoor,Abbas Syed Muzahir,Yousaf Jawad,Almajali Eqab 한국전자파학회 2022 Journal of Electromagnetic Engineering and Science Vol.22 No.4
In this work, a design of a transition from a standard D-band waveguide to substrate integrated waveguide (SIW) technology is presented for 6G applications. The waveguide is connected to an SIW by carving a slot at the bottom metal of the printed circuit board (PCB). A pair of vias is added to shift the inband null to a higher frequency, whereas a parasitic patch is used to improve impedance matching. A prototype of a back-to-back SIW transition is fabricated and measured using D-band VNA extenders. The measurement shows a −10 dB impedance bandwidth of 26.5 GHz (135–161.5 GHz) and a 3 dB bandwidth of 28 GHz (133.8–161.8 GHz). The transition can be integrated with a D-band antenna for 6G applications.