A Compact Design of High-Gain Phased Array Antenna for THz and 6G Communication Networks

H. J. Basherlou; N. O. Parchin; L. Manjakkal; C. H. See; A. S. I. Amar; Y. M. Madany; M. Shen

doi:10.1109/IC-FTAI62324.2024.10950045

A Compact Design of High-Gain Phased Array Antenna for THz and 6G Communication Networks

H. J. Basherlou, N. O. Parchin, L. Manjakkal, C. H. See, A. S. I. Amar, Y. M. Madany, M. Shen

Publikation: Bidrag til bog/antologi/rapport/konference proceeding › Konferenceartikel i proceeding › Forskning › peer review

Abstract

This paper explores the characteristics of an innovative linear phased array designed to provide high gain and steerable radiation patterns, tailored to meet the demands of upcoming 6G networks. The array features a schematic with eight modified dipole elements arranged in a 1×8 linear format. To improve the radiation efficiency of the dipole resonators, rectangular directors are strategically placed adjacent to each resonator. These compact resonators utilize microstrip-line feeds, optimizing their design. The proposed phased array achieves an impedance bandwidth of 1.85 to 2.15 THz at −10 dB, delivering radiation gains exceeding 12 dBi across various angles. This performance meets the requirements for 6G communications.

Originalsprog	Engelsk
Titel	2024 International Conference on Future Telecommunications and Artificial Intelligence (IC-FTAI)
Antal sider	4
Forlag	IEEE (Institute of Electrical and Electronics Engineers)
Publikationsdato	2 jan. 2025
Sider	1-4
Artikelnummer	10950045
ISBN (Trykt)	979-8-3315-3409-7
DOI	https://doi.org/10.1109/IC-FTAI62324.2024.10950045
Status	Udgivet - 2 jan. 2025
Begivenhed	2024 International Conference on Future Telecommunications and Artificial Intelligence (IC-FTAI) - Alexandria, Egypt Varighed: 31 dec. 2024 → 2 jan. 2025

Konference

Konference	2024 International Conference on Future Telecommunications and Artificial Intelligence (IC-FTAI)
Lokation	Alexandria, Egypt
Periode	31/12/2024 → 02/01/2025

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10.1109/IC-FTAI62324.2024.10950045

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Citationsformater

Basherlou, H. J., Parchin, N. O., Manjakkal, L., See, C. H., Amar, A. S. I., Madany, Y. M., & Shen, M. (2025). A Compact Design of High-Gain Phased Array Antenna for THz and 6G Communication Networks. I 2024 International Conference on Future Telecommunications and Artificial Intelligence (IC-FTAI) (s. 1-4). Artikel 10950045 IEEE (Institute of Electrical and Electronics Engineers). https://doi.org/10.1109/IC-FTAI62324.2024.10950045

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title = "A Compact Design of High-Gain Phased Array Antenna for THz and 6G Communication Networks",

abstract = "This paper explores the characteristics of an innovative linear phased array designed to provide high gain and steerable radiation patterns, tailored to meet the demands of upcoming 6G networks. The array features a schematic with eight modified dipole elements arranged in a 1×8 linear format. To improve the radiation efficiency of the dipole resonators, rectangular directors are strategically placed adjacent to each resonator. These compact resonators utilize microstrip-line feeds, optimizing their design. The proposed phased array achieves an impedance bandwidth of 1.85 to 2.15 THz at −10 dB, delivering radiation gains exceeding 12 dBi across various angles. This performance meets the requirements for 6G communications.",

keywords = "Phased arrays, 6G mobile communication, Microstrip resonators, Terahertz radiation, Linear antenna arrays, Microstrip, Resonators, Gain, Terahertz communications, Antenna radiation patterns",

author = "Basherlou, {H. J.} and Parchin, {N. O.} and L. Manjakkal and See, {C. H.} and Amar, {A. S. I.} and Madany, {Y. M.} and M. Shen",

year = "2025",

month = jan,

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doi = "10.1109/IC-FTAI62324.2024.10950045",

language = "English",

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booktitle = "2024 International Conference on Future Telecommunications and Artificial Intelligence (IC-FTAI)",

publisher = "IEEE (Institute of Electrical and Electronics Engineers)",

address = "United States",

note = "2024 International Conference on Future Telecommunications and Artificial Intelligence (IC-FTAI) ; Conference date: 31-12-2024 Through 02-01-2025",

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Basherlou, HJ, Parchin, NO, Manjakkal, L, See, CH, Amar, ASI, Madany, YM & Shen, M 2025, A Compact Design of High-Gain Phased Array Antenna for THz and 6G Communication Networks. i 2024 International Conference on Future Telecommunications and Artificial Intelligence (IC-FTAI)., 10950045, IEEE (Institute of Electrical and Electronics Engineers), s. 1-4, 2024 International Conference on Future Telecommunications and Artificial Intelligence (IC-FTAI), 31/12/2024. https://doi.org/10.1109/IC-FTAI62324.2024.10950045

A Compact Design of High-Gain Phased Array Antenna for THz and 6G Communication Networks. / Basherlou, H. J.; Parchin, N. O.; Manjakkal, L. et al.
2024 International Conference on Future Telecommunications and Artificial Intelligence (IC-FTAI). IEEE (Institute of Electrical and Electronics Engineers), 2025. s. 1-4 10950045.

Publikation: Bidrag til bog/antologi/rapport/konference proceeding › Konferenceartikel i proceeding › Forskning › peer review

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AU - Basherlou, H. J.

AU - Parchin, N. O.

AU - Manjakkal, L.

AU - See, C. H.

AU - Amar, A. S. I.

AU - Madany, Y. M.

AU - Shen, M.

PY - 2025/1/2

Y1 - 2025/1/2

N2 - This paper explores the characteristics of an innovative linear phased array designed to provide high gain and steerable radiation patterns, tailored to meet the demands of upcoming 6G networks. The array features a schematic with eight modified dipole elements arranged in a 1×8 linear format. To improve the radiation efficiency of the dipole resonators, rectangular directors are strategically placed adjacent to each resonator. These compact resonators utilize microstrip-line feeds, optimizing their design. The proposed phased array achieves an impedance bandwidth of 1.85 to 2.15 THz at −10 dB, delivering radiation gains exceeding 12 dBi across various angles. This performance meets the requirements for 6G communications.

AB - This paper explores the characteristics of an innovative linear phased array designed to provide high gain and steerable radiation patterns, tailored to meet the demands of upcoming 6G networks. The array features a schematic with eight modified dipole elements arranged in a 1×8 linear format. To improve the radiation efficiency of the dipole resonators, rectangular directors are strategically placed adjacent to each resonator. These compact resonators utilize microstrip-line feeds, optimizing their design. The proposed phased array achieves an impedance bandwidth of 1.85 to 2.15 THz at −10 dB, delivering radiation gains exceeding 12 dBi across various angles. This performance meets the requirements for 6G communications.

KW - Phased arrays

KW - 6G mobile communication

KW - Microstrip resonators

KW - Terahertz radiation

KW - Linear antenna arrays

KW - Microstrip

KW - Resonators

KW - Gain

KW - Terahertz communications

KW - Antenna radiation patterns

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DO - 10.1109/IC-FTAI62324.2024.10950045

M3 - Article in proceeding

SN - 979-8-3315-3409-7

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EP - 4

BT - 2024 International Conference on Future Telecommunications and Artificial Intelligence (IC-FTAI)

PB - IEEE (Institute of Electrical and Electronics Engineers)

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Y2 - 31 December 2024 through 2 January 2025

ER -

Basherlou HJ, Parchin NO, Manjakkal L, See CH, Amar ASI, Madany YM et al. A Compact Design of High-Gain Phased Array Antenna for THz and 6G Communication Networks. I 2024 International Conference on Future Telecommunications and Artificial Intelligence (IC-FTAI). IEEE (Institute of Electrical and Electronics Engineers). 2025. s. 1-4. 10950045 doi: 10.1109/IC-FTAI62324.2024.10950045

A Compact Design of High-Gain Phased Array Antenna for THz and 6G Communication Networks

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