Research Article
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Year 2020, Volume: 16 Issue: 4, 355 - 360, 30.12.2020

Abstract

References

  • Isaac, AA, Al-Rizzo, H, Yahya, S, Al-Wahhamy, A, Tariq, SZ. 2020. Miniaturized MIMO antenna array of two vertical monopoles embedded inside a planar decoupling network for the 2.4 GHz ISM band. IET Microwaves, Antennas & Propagation; 14(1): 132-140.
  • Li, PK, You, CJ, Yu, HF, Cheng, YJ, Yang, YW, Deng, JH. 2018. A high frequency ratio quadri-band frequency independently tunable antenna with spurious-mode suppression. Microwave and Optical Technology Letters; 60: 1445–1452.
  • Okan, T. 2020. Design and analysis of a quad-band substrate-integrated- waveguide cavity backed slot antenna for 5G applications. International Journal of RF and Microwave Computer Aided Engineering; e22236.
  • Cui, L, Guo, J, Liu, Y, Sim, C. 2019. An 8-Element Dual-Band MIMO Antenna with Decoupling Stub for 5G Smartphone Applications. IEEE Antennas and Wireless Propagation Letters; 18(10): 2095-2099.
  • Hatami, N, Nourinia, J, Ghobadi, C, Majidzadeh, M, Azarm, B. 2019. High Inter-Element Isolation and WLAN Filtering Mechanism: A Compact MIMO Antenna Scheme. AEU - International Journal of Electronics and Communications; 109: 43-54.
  • Mondal, K, Sarkar, PP. 2017. Dual band compact monopole antenna for ISM 2.4/5.8 frequency bands with bluetooth, Wi-Fi, and mobile applications. Microwave and Optical Technology Letters; 59(5): 1061–1065.
  • Pazin, L, Kogan, I, Leviatan, Y. 2008. Flat-plate triangular monopole antenna for Wi-Fi/WiMAX/DVB-H applications. Microwave and Optical Technology Letters; 50(11): 2922-2925.
  • Werner, PL, Werner, DH. 2005. Design synthesis of miniature multiband monopole antennas with application to ground-based and vehicular communication systems. IEEE Antennas and Wireless Propagation Letters; 4: 104-106.
  • Tetik, E, Tetik, GD. 2018. The effect of a metamaterial based wearable monopole antenna on the human body. Celal Bayar University Journal of Science; 14(1): 97-93.
  • Gupta, A, Kansal, A, Chawla, P. 2019. Design of a patch antenna with square ring-shaped-coupled ground for on-/off body communication. International Journal of Electronics; 106(12): 1814-1828.
  • Toktaş, A, Yerlikaya, M, Yiğit, E. 2016. Microstrip-fed Triangular UWB Microstrip Antenna Based on DGS. International Journal of Applied Mathematics Electronics and Computers; (Special Issue-1): 43-47.
  • Biçer, M, Akdağlı, A. 2017. Designing a compact monopole microstrip antenna operating at ultra-wide band for microwave imaging applications. Turkish Journal of Engineering; 1(2): 69-66.
  • Okan, T. 2020. A compact octagonal‐ring monopole antenna for super wideband applications. Microwave and Optical Technology Letters; 62(3): 1237-1244.
  • Kuzu, S, Akçam, N. 2017. Array antenna using defected ground structure shaped with fractal form generated by Apollonius circle. IEEE Antennas and Wireless Propagation Letters; 16: 1020-1023.
  • Mahmoud, KR, Montaser, AM. 2018. Performance of tri-band multi-polarized array antenna for 5G mobile base station adopting polarization and directivity control. IEEE Access; 6: 8682-8694.
  • Okan, T, Akçam N. 2018. Analysis of antennas around NURBS surfaces by using a hybrid method. Radioengineering; 27(3): 703-710.
  • Tripathi, S, Mohan, A, Yadav, S. 2015. A compact koch fractal UWB MIMO antenna with WLAN band-rejection. IEEE Antennas and Wireless Propagation Letters; 14 (4): 1565–1568.
  • Ali, WAE, Ibrahim, AA. 2017. A compact double-sided MIMO antenna with an improved isolation for UWB applications. AEU - International Journal of Electronics and Communications; 82: 7–13.
  • Iqbal, A, Saraereh, OA, Ahmad, AW, Bashir, S. 2018. Mutual coupling reduction using F- shaped stubs in UWB MIMO antenna. IEEE Access; 6: 2755–2759.
  • Yu, K, Li, Y, Liu, X. 2018. Mutual coupling reduction of a MIMO antenna array using 3-D novel meta-material structures. ACES Journal; 33(7): 758-763.

High Isolation Wideband Multiple-Input Multiple-Output Antennas for Millimeter Wave Applications

Year 2020, Volume: 16 Issue: 4, 355 - 360, 30.12.2020

Abstract

A planar 2×2 and 4×4 multiple-input multiple-output (MIMO) antennas are designed and analyzed in this study. The individual antenna elements that form the MIMO structure are located perpendicular to each other in order to facilitate polarization diversity. Except a notch band at 4.3 GHz, the 2×2 antenna nearly covers the entire 2.41-31.4 GHz frequency band. It is similar for the 4×4 antenna that has tri-band characteristic, where the impedance bandwidth (|S_11 |≤-10 dB) values are determined as 1.4, 10.05 and 16.26 GHz. Beside these high bandwidth results, both MIMO antennas have perfect isolation characteristic which is important to prevent coupling in MIMO systems. The proposed MIMO antennas are convenient to be used in all S (2-4 GHz), C (4-8 GHz), X (8-12 GHz), Ku (12-18 GHz) and K-bands (18-27 GHz). Furthermore, omnidirectional radiation patterns are observed at the resonance frequencies, and the reported 2×2 and 4×4 antennas have compact sizes of 80×40×1 mm3 (64.5λ×32.25λ ×0.8λ) and 80×80×1 mm3 (64.5λ×64.5λ ×0.8λ), respectively.

References

  • Isaac, AA, Al-Rizzo, H, Yahya, S, Al-Wahhamy, A, Tariq, SZ. 2020. Miniaturized MIMO antenna array of two vertical monopoles embedded inside a planar decoupling network for the 2.4 GHz ISM band. IET Microwaves, Antennas & Propagation; 14(1): 132-140.
  • Li, PK, You, CJ, Yu, HF, Cheng, YJ, Yang, YW, Deng, JH. 2018. A high frequency ratio quadri-band frequency independently tunable antenna with spurious-mode suppression. Microwave and Optical Technology Letters; 60: 1445–1452.
  • Okan, T. 2020. Design and analysis of a quad-band substrate-integrated- waveguide cavity backed slot antenna for 5G applications. International Journal of RF and Microwave Computer Aided Engineering; e22236.
  • Cui, L, Guo, J, Liu, Y, Sim, C. 2019. An 8-Element Dual-Band MIMO Antenna with Decoupling Stub for 5G Smartphone Applications. IEEE Antennas and Wireless Propagation Letters; 18(10): 2095-2099.
  • Hatami, N, Nourinia, J, Ghobadi, C, Majidzadeh, M, Azarm, B. 2019. High Inter-Element Isolation and WLAN Filtering Mechanism: A Compact MIMO Antenna Scheme. AEU - International Journal of Electronics and Communications; 109: 43-54.
  • Mondal, K, Sarkar, PP. 2017. Dual band compact monopole antenna for ISM 2.4/5.8 frequency bands with bluetooth, Wi-Fi, and mobile applications. Microwave and Optical Technology Letters; 59(5): 1061–1065.
  • Pazin, L, Kogan, I, Leviatan, Y. 2008. Flat-plate triangular monopole antenna for Wi-Fi/WiMAX/DVB-H applications. Microwave and Optical Technology Letters; 50(11): 2922-2925.
  • Werner, PL, Werner, DH. 2005. Design synthesis of miniature multiband monopole antennas with application to ground-based and vehicular communication systems. IEEE Antennas and Wireless Propagation Letters; 4: 104-106.
  • Tetik, E, Tetik, GD. 2018. The effect of a metamaterial based wearable monopole antenna on the human body. Celal Bayar University Journal of Science; 14(1): 97-93.
  • Gupta, A, Kansal, A, Chawla, P. 2019. Design of a patch antenna with square ring-shaped-coupled ground for on-/off body communication. International Journal of Electronics; 106(12): 1814-1828.
  • Toktaş, A, Yerlikaya, M, Yiğit, E. 2016. Microstrip-fed Triangular UWB Microstrip Antenna Based on DGS. International Journal of Applied Mathematics Electronics and Computers; (Special Issue-1): 43-47.
  • Biçer, M, Akdağlı, A. 2017. Designing a compact monopole microstrip antenna operating at ultra-wide band for microwave imaging applications. Turkish Journal of Engineering; 1(2): 69-66.
  • Okan, T. 2020. A compact octagonal‐ring monopole antenna for super wideband applications. Microwave and Optical Technology Letters; 62(3): 1237-1244.
  • Kuzu, S, Akçam, N. 2017. Array antenna using defected ground structure shaped with fractal form generated by Apollonius circle. IEEE Antennas and Wireless Propagation Letters; 16: 1020-1023.
  • Mahmoud, KR, Montaser, AM. 2018. Performance of tri-band multi-polarized array antenna for 5G mobile base station adopting polarization and directivity control. IEEE Access; 6: 8682-8694.
  • Okan, T, Akçam N. 2018. Analysis of antennas around NURBS surfaces by using a hybrid method. Radioengineering; 27(3): 703-710.
  • Tripathi, S, Mohan, A, Yadav, S. 2015. A compact koch fractal UWB MIMO antenna with WLAN band-rejection. IEEE Antennas and Wireless Propagation Letters; 14 (4): 1565–1568.
  • Ali, WAE, Ibrahim, AA. 2017. A compact double-sided MIMO antenna with an improved isolation for UWB applications. AEU - International Journal of Electronics and Communications; 82: 7–13.
  • Iqbal, A, Saraereh, OA, Ahmad, AW, Bashir, S. 2018. Mutual coupling reduction using F- shaped stubs in UWB MIMO antenna. IEEE Access; 6: 2755–2759.
  • Yu, K, Li, Y, Liu, X. 2018. Mutual coupling reduction of a MIMO antenna array using 3-D novel meta-material structures. ACES Journal; 33(7): 758-763.
There are 20 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Tayfun Okan

Publication Date December 30, 2020
Published in Issue Year 2020 Volume: 16 Issue: 4

Cite

APA Okan, T. (2020). High Isolation Wideband Multiple-Input Multiple-Output Antennas for Millimeter Wave Applications. Celal Bayar Üniversitesi Fen Bilimleri Dergisi, 16(4), 355-360.
AMA Okan T. High Isolation Wideband Multiple-Input Multiple-Output Antennas for Millimeter Wave Applications. CBUJOS. December 2020;16(4):355-360.
Chicago Okan, Tayfun. “High Isolation Wideband Multiple-Input Multiple-Output Antennas for Millimeter Wave Applications”. Celal Bayar Üniversitesi Fen Bilimleri Dergisi 16, no. 4 (December 2020): 355-60.
EndNote Okan T (December 1, 2020) High Isolation Wideband Multiple-Input Multiple-Output Antennas for Millimeter Wave Applications. Celal Bayar Üniversitesi Fen Bilimleri Dergisi 16 4 355–360.
IEEE T. Okan, “High Isolation Wideband Multiple-Input Multiple-Output Antennas for Millimeter Wave Applications”, CBUJOS, vol. 16, no. 4, pp. 355–360, 2020.
ISNAD Okan, Tayfun. “High Isolation Wideband Multiple-Input Multiple-Output Antennas for Millimeter Wave Applications”. Celal Bayar Üniversitesi Fen Bilimleri Dergisi 16/4 (December 2020), 355-360.
JAMA Okan T. High Isolation Wideband Multiple-Input Multiple-Output Antennas for Millimeter Wave Applications. CBUJOS. 2020;16:355–360.
MLA Okan, Tayfun. “High Isolation Wideband Multiple-Input Multiple-Output Antennas for Millimeter Wave Applications”. Celal Bayar Üniversitesi Fen Bilimleri Dergisi, vol. 16, no. 4, 2020, pp. 355-60.
Vancouver Okan T. High Isolation Wideband Multiple-Input Multiple-Output Antennas for Millimeter Wave Applications. CBUJOS. 2020;16(4):355-60.