Helga Schultz: RGW1 Die Wirtschaft im RGW Von der sozialistischen Transformation zur finalen Krise.
Circular Polarization Antennas using Gap Waveguide ... - Presentation.pdf1. Simple, compact and low...
Transcript of Circular Polarization Antennas using Gap Waveguide ... - Presentation.pdf1. Simple, compact and low...
Dayan Pérez-Quintana 1,2, Alicia Torres-García 1,2, Iñigo Ederra 1,2, Miguel Beruete 1,2
Circular Polarization Antennas using Gap Waveguide Technologies at 60 GHz
1 Department of Electrical, Electronic and Communications Engineering, Public University of Navarra, Spain
2 Institute of Smart Cities (ISC), Public University of Navarra, Navarra, Spain
Introduction Theory Simulation Experimental Results Conclusion
References[1] Ref. 1 A. Berenguer, V. Fusco, D. E. Zelenchuk, D. Sanchez-Escuderos, M. Baquero-Escudero, and V. E. Boria-Esbert,“Propagation Characteristics of Groove Gap Waveguide Below and Above Cutoff,” IEEE Trans. Microw. Theory Tech., vol. 64, no.1, pp. 27–36, Jan. 2016.[2] Ref. 2A. U. Zaman and P. Kildal, “Wide-Band Slot Antenna Arrays With Single-Layer Corporate-Feed Network in Ridge GapWaveguide Technology,” IEEE Trans. Antennas Propag., vol. 62, no. 6, pp. 2992–3001, 2014.
Gap Waveguide Technology Advantages
• Low loss (most of the designs are fully metallic)
• No need of electric contact
• Adaptability to plane surfaces
• Lower manufacturing cost
Circular polarization (CP) in wireless communications systems
has several advantages over linear polarization: CP does not
require polarization alignment between the transmitter and the
receiver and is more robust against multipath effects.
Why use Circular Polarization?
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Groove Gap Waveguide [1]
Ridge Gap Waveguide [2]
Microstrip Gap Waveguide
Introduction Theory Simulation Conclusion
Design and Circular Polarization Analysis
Dayan Pérez-Quintana 1,2, Alicia Torres-García 1,2, Iñigo Ederra 1,2, Miguel Beruete 1,2
Circular Polarization Antennas using Gap Waveguide Technologies at 60 GHz
Electric Field Distribution at 63.5 GHz
Surface Currents at 63.5 GHz
Electric Field and Surface Currents at 63.5 GHz
Experimental Results
Introduction Theory Simulation Conclusion
Geometry of the model Diamond Horn Groove AntennaGeometry of the model Diamond Antenna
Dayan Pérez-Quintana 1,2, Alicia Torres-García 1,2, Iñigo Ederra 1,2, Miguel Beruete 1,2
Circular Polarization Antennas using Gap Waveguide Technologies at 60 GHz
Diamond Antenna (D)Diamond Horn Groove
Antenna (DHG)
No
rmal
ized
Am
plit
ud
e(d
B)
XPD > 15 dB
Abs RHCP LHCP
Copolar and crosspolar radiation pattern
Radiation Pattern at 63.5 GHz
XPD > 15 dB
Copolar and crosspolar radiation pattern
Abs RHCP LHCP
Radiation Pattern at 63.5 GHz
Experimental Results
Introduction Theory Simulation Experimental Results Conclusion
Experimental Results Diamond Antenna
Dayan Pérez-Quintana 1,2, Alicia Torres-García 1,2, Iñigo Ederra 1,2, Miguel Beruete 1,2
Circular Polarization Antennas using Gap Waveguide Technologies at 60 GHz
WR-15 Feeding System
BWSIM = 14.55 % (58.95 - 68.16 GHz)
BWMEA = 13.90 % (60.50 - 69.30 GHz)
BWSIM= 17.06 % (59 – 69.8 GHz)
BWMEA = 12.79 % (59.3 – 67.4 GHz)
BWtotal = 10.74 % (60.5 – 67.4 GHz)
Gainmax = 5.49 dB @ 67 GHz
S11
Axial Ratio
Practical Operation BW
Introduction Theory Simulation Conclusion
Experimental Results Diamond Horn Groove Antenna
Dayan Pérez-Quintana 1,2, Alicia Torres-García 1,2, Iñigo Ederra 1,2, Miguel Beruete 1,2
Circular Polarization Antennas using Gap Waveguide Technologies at 60 GHz
WR-15 Feeding System
BWSIM = 14.17 % (59.0 - 68.0 GHz)
BWMEA = 14.64 % (60.3 - 69.6 GHz)
BWSIM= 17.85 % (59.3 – 70.0 GHz)
BWMEA = 17.32 % (59.0 – 70.0 GHz)
BWtotal = 14.69 % (60.3 – 69.6 GHz)
Gainmax = 11.12 dB @ 67 GHz
S11
Axial Ratio
Practical Operation BW
Experimental Results
Introduction Theory Simulation Setup Results Conclusion
1. Simple, compact and low profile antenna using RGW technology.
2. Novel and simple mechanism to generate circular polarization.
3. BW above 14% with respect to the center frequency using the DHG antenna.
4. Maximum gain of 11.12 dB at 67 GHz.
Dayan Pérez-Quintana 1,2, Alicia Torres-García 1,2, Iñigo Ederra 1,2, Miguel Beruete 1,2
Circular Polarization Antennas using Gap Waveguide Technologies at 60 GHz
1 Department of Electrical, Electronic and Communications Engineering, Public University of Navarra, Spain
2 Institute of Smart Cities (ISC), Public University of Navarra, Navarra, Spain
Publications
1. D. Pérez-Quintana, A. E. Torres-García, I. Ederra and M. Beruete, "Compact Groove Diamond Antenna in Gap Waveguide Technology With BroadbandCircular Polarization at Millimeter Waves," in IEEE Transactions on Antennas and Propagation, vol. 68, no. 8, pp. 5778-5783, Aug. 2020, doi:10.1109/TAP.2020.2996364.
2. D. Pérez-Quintana, I. Ederra and M. Beruete, "Bull’s-Eye Antenna with Circular Polarization at Millimeter Waves based on Ridge Gap Waveguide Technology,"in IEEE Transactions on Antennas and Propagation, doi: 10.1109/TAP.2020.3019565.
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