Wideband SIW Horn Antenna with phase correction for New Generation Beam Streerable Arrays

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Resumé

This paper presents a new SIW horn antenna with high performance in the mm-wave bands for the next generation mobile devices. The proposed antenna is integrated in a double layer of Rogers RO4003C substrate and requires a clearance of only 3 mm. Air vias are etched in the substrate in a specific portion of the horn aperture, in order to correct the phase of the electromagnetic wave and allow the beam pointing in the desired direction. Moreover, a tapered ladder transition is placed at the horn aperture to improve the impedance matching and enhance the radiation performance. Simulation results prove that the 6 dB bandwidth is wider than 40 GHz in the frequency range 24 − 64 GHz. In particular, the same beam pointing is guaranteed over the whole bandwidth with realized gain of 6.4, 8.5 and 8.7 dBi at 28, 38 and 60 GHz respectively. Simulations including two symmetric elements pointing opposite directions and a central element show that the angle of 90° can be covered with peak gain of 7.5 dBi at 28 GHz.
OriginalsprogEngelsk
Titel90th Vehicular Technology Conference: VTC2019-Fall
ForlagIEEE
StatusAccepteret/In press - 24 jul. 2019
Begivenhed2019 IEEE 90th Vehicular Technology Conference - Waikiki Beach Marriott Resort & Spa, Honolulu, USA
Varighed: 22 sep. 201925 sep. 2019
Konferencens nummer: 90
http://www.ieeevtc.org/vtc2019fall/

Konference

Konference2019 IEEE 90th Vehicular Technology Conference
Nummer90
LokationWaikiki Beach Marriott Resort & Spa
LandUSA
ByHonolulu
Periode22/09/201925/09/2019
Internetadresse

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Horn antennas
Bandwidth
Ladders
Substrates
Mobile devices
Electromagnetic waves
Antennas
Radiation
Air

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@inproceedings{cf111b78ea6e486ab82a96fdf70cda2a,
title = "Wideband SIW Horn Antenna with phase correction for New Generation Beam Streerable Arrays",
abstract = "This paper presents a new SIW horn antenna with high performance in the mm-wave bands for the next generation mobile devices. The proposed antenna is integrated in a double layer of Rogers RO4003C substrate and requires a clearance of only 3 mm. Air vias are etched in the substrate in a specific portion of the horn aperture, in order to correct the phase of the electromagnetic wave and allow the beam pointing in the desired direction. Moreover, a tapered ladder transition is placed at the horn aperture to improve the impedance matching and enhance the radiation performance. Simulation results prove that the 6 dB bandwidth is wider than 40 GHz in the frequency range 24 − 64 GHz. In particular, the same beam pointing is guaranteed over the whole bandwidth with realized gain of 6.4, 8.5 and 8.7 dBi at 28, 38 and 60 GHz respectively. Simulations including two symmetric elements pointing opposite directions and a central element show that the angle of 90° can be covered with peak gain of 7.5 dBi at 28 GHz.",
author = "Paola, {Carla di} and Kun Zhao and Shuai Zhang and Pedersen, {Gert Fr{\o}lund}",
year = "2019",
month = "7",
day = "24",
language = "English",
booktitle = "90th Vehicular Technology Conference: VTC2019-Fall",
publisher = "IEEE",
address = "United States",

}

Paola, CD, Zhao, K, Zhang, S & Pedersen, GF 2019, Wideband SIW Horn Antenna with phase correction for New Generation Beam Streerable Arrays. i 90th Vehicular Technology Conference: VTC2019-Fall. IEEE, Honolulu, USA, 22/09/2019.

Wideband SIW Horn Antenna with phase correction for New Generation Beam Streerable Arrays. / Paola, Carla di; Zhao, Kun; Zhang, Shuai; Pedersen, Gert Frølund.

90th Vehicular Technology Conference: VTC2019-Fall. IEEE, 2019.

Publikation: Bidrag til bog/antologi/rapport/konference proceedingKonferenceartikel i proceedingForskningpeer review

TY - GEN

T1 - Wideband SIW Horn Antenna with phase correction for New Generation Beam Streerable Arrays

AU - Paola, Carla di

AU - Zhao, Kun

AU - Zhang, Shuai

AU - Pedersen, Gert Frølund

PY - 2019/7/24

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N2 - This paper presents a new SIW horn antenna with high performance in the mm-wave bands for the next generation mobile devices. The proposed antenna is integrated in a double layer of Rogers RO4003C substrate and requires a clearance of only 3 mm. Air vias are etched in the substrate in a specific portion of the horn aperture, in order to correct the phase of the electromagnetic wave and allow the beam pointing in the desired direction. Moreover, a tapered ladder transition is placed at the horn aperture to improve the impedance matching and enhance the radiation performance. Simulation results prove that the 6 dB bandwidth is wider than 40 GHz in the frequency range 24 − 64 GHz. In particular, the same beam pointing is guaranteed over the whole bandwidth with realized gain of 6.4, 8.5 and 8.7 dBi at 28, 38 and 60 GHz respectively. Simulations including two symmetric elements pointing opposite directions and a central element show that the angle of 90° can be covered with peak gain of 7.5 dBi at 28 GHz.

AB - This paper presents a new SIW horn antenna with high performance in the mm-wave bands for the next generation mobile devices. The proposed antenna is integrated in a double layer of Rogers RO4003C substrate and requires a clearance of only 3 mm. Air vias are etched in the substrate in a specific portion of the horn aperture, in order to correct the phase of the electromagnetic wave and allow the beam pointing in the desired direction. Moreover, a tapered ladder transition is placed at the horn aperture to improve the impedance matching and enhance the radiation performance. Simulation results prove that the 6 dB bandwidth is wider than 40 GHz in the frequency range 24 − 64 GHz. In particular, the same beam pointing is guaranteed over the whole bandwidth with realized gain of 6.4, 8.5 and 8.7 dBi at 28, 38 and 60 GHz respectively. Simulations including two symmetric elements pointing opposite directions and a central element show that the angle of 90° can be covered with peak gain of 7.5 dBi at 28 GHz.

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