I. J. of Electrical & Electronics Research
Research Article | 
Wide Bandwidth Tri-Band MIMO Antenna Design for 5G Communication
Author(s): Megha Soni, Ajay Dadoriya and Leeladhar Malviya*
Published In : International Journal of Electrical and Electronics Research (IJEER) Volume 12, Issue 4
Publisher : FOREX Publication
Published : 30 November 2024
e-ISSN : 2347-470X
Page(s) : 1281-1286
Abstract
Wireless communication research is currently focused on 5G. On an FR4 substrate, a building-like structure with two slot-based planar multiple input multiple output (MIMO) antenna has been designed. 4.3 is the dielectric constant, and the substrate thickness is 1.6mm. The proposed antenna is designed and simulated for 5G applications using CST microwave studio and HFSS at 24.25GHz, 29.25GHz, and 32.40GHz. According to the simulated results, the VSWR is lower than 3:1 and the return loss at both ports is -43.27dB, -60.55dB, and –42.61dB at 29.25GHz, 34.20GHz, and 34.075GHz resonating frequencies respectively. Isolation between both ports is better. At 24.25GHz, 29.25GHz, and 32.40GHz the proposed design achieves a gain of 5.1dBi, 5.5dBi, and 3.5dBi respectively. The structure is fabricated and measurement is carried out. The simulated and the measured results shows good agreement.
Keywords: 5G, High Gain, MIMO, Wide bandwidth.
Megha Soni, Amity University Gwalior, India; Email: soni_megha1987@yahoo.co.in
Ajay Dadoriya, Amity University Gwalior, India; Email: akdadoria@gwa.amity.edu
Leeladhar Malviya*, Shri G.S. Institute of Technology and Science Indore, India; Email: ldmalviya@gmail.com
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[1] Wei, X., Zheng, K., Shen, X. S., ed.: “5G mobile communications”,(Springer, Switzerland, 2017).
-
[2] Andrews, J.G., Buzzi, S., Choi, W., et al.: “What will 5G be?”,IEEE J. Sel.AreasCommun., 2014, 32, (6), pp. 1065–1082.
-
[3] Pi, Z., Khan, F.: “An Introduction to millimeter-wave mobile broadband systems”, IEEE Commun. Mag., 2011, 49, (6), pp. 101–107.
-
[4] Rappaport, T. S., Sun, S., Mayzus, R., et al.: “Millimeter wave mobilecommunications for 5G cellular: it will work!”,IEEE Access, 2013, 1, pp.335–349.
-
[5] Ghosh, A.: “The 5G mmWave radio revolution”, Microw. J., 2016, 59, (9 PartI), pp. 3–10
-
[6] "Resolution Com6/20, provisional final acts WRC-15, WRC-15”(ITU, Geneva), pp. 424–426, http://www.itu.int/dms_pub/itur/opb/act/R-ACTWRC.11-2015-PDF-E.pdf.
-
[7] “Use of Spectrum Bands above 24 GHz for Mobile Radio Services”, GNDocket No. 14-177, Notice of Proposed Rulemaking, 15 FCC Record 138A1(rel. Oct. 23, 2015).
-
[8] Khattak, Muhammad &Sohail, Amir & Khan, Ubaid &Ullah, Zaka&Witjaksono, Gunawan. (2019). “Elliptical Slot Circular Patch Antenna Array with Dual Band Behaviour for Future 5G Mobile Communication Networks”. Progress in Electromagnetics Research C. 89. 133-147. 10.2528/PIERC18101401.
-
[9] Ahmad, W. and W. T. Khan, “Small form factor dual band (28/38 GHz) PIFA antenna for 5G applications,” 2017 IEEE MTT-S International Conference on Microwaves for Intelligent Mobility (ICMIM), 21–24, IEEE, March 2017.
-
[10] Y. Rahayu and M. I. Hidayat, "Design of 28/38 GHz Dual-Band Triangular-Shaped Slot Microstrip Antenna Array for 5G Applications," 2018 2nd International Conference on Telematics and Future Generation Networks (TAFGEN), Kuching, 2018, pp. 93-97.
-
[11] C. Chu, J. Zhu, S. Liao, A. Zhu and Q. Xue, "28/38 GHz Dual-band Dual-polarized Highly Isolated Antenna for 5G Phased Array Applications," 2019 IEEE MTT-S International Wireless Symposium (IWS), Guangzhou, China, 2019, pp. 1-3.
-
[12] N. Ashraf, O. Haraz, M. A. Ashraf and S. Alshebeili, "28/38-GHz dual-band millimeter wave SIW array antenna with EBG structures for 5G applications," 2015 International Conference on Information and Communication Technology Research (ICTRC), Abu Dhabi, 2015, pp. 5-8.
-
[13] H. Ullah, F. A. Tahir and M. U. Khan, "Dual-band planar spiral monopole antenna for 28/38 GHz frequency bands," 2017 IEEE International Symposium on Antennas and Propagation & USNC/URSI National Radio Science Meeting, San Diego, CA, 2017, pp. 761-762.
-
[14] Ali, M. M. M. and A. R. Sebak, “Dual band (28/38 GHz) CPW slot directive antenna for future 5G cellular applications,” 2016 IEEE International Symposium on Antennas and Propagation (APSURSI), 399–400, IEEE, June 2016.
-
[15] Kamal, Md& Islam, Md& Uddin, Md& Imran, Abu. (2018). “Design of a Tri-Band Microstrip Patch Antenna for 5G Application”. 1-3. 10.1109/IC4ME2.2018.8465627.
-
[16] Rahman, Mm & Islam, & Wong, &Alam, (2019). “Performance Analysis of a Defected Ground-Structured Antenna Loaded with StubSlot for 5G Communication”. Sensors. 19. 2634. 10.3390/s19112634.
-
[17] C. ABDELHAMID, M. DAGHARI, H. SAKLI and C. HAMROUNI, “A New UWB-MIMO Multi-Antennas With High Isolation For Satellite Communications,”2019 15th International Wireless Communications & Mobile Computing Conference (IWCMC), Tangier, Morocco, 2019, pp. 152-155.
-
[18] Cao, Xia, Xia, Yingqing, Wu, Ling, Wu, Xiaolin, “Tri-band MIMO antenna design based on characteristic modes manipulation”, AEU - International Journal of Electronics and Communications, 155, 154318, 2022, 2022/10/01/, 1434-8411, https://doi.org/10.1016/j.aeue.2022.154318.
-
[19] Quan Fang, DaweiMi, and Ying-Zeng Yin, "A Tri-Band MIMO Antenna for WLAN/WiMAX Application," Progress In Electromagnetics Research Letters, Vol. 55, 75-80, 2015.doi:10.2528/PIERL15070202.
-
[20] Ali, Ayyaz, Munir, Mehr E, Nasralla, Moustafa M, Esmail, Maged A, Al-Gburi, Ahmed Jamal Abdullah, Bhatti, Farooq Ahmed, “Design process of a compact Tri-Band MIMO antenna with wideband characteristics for sub-6 GHz, Ku-band, and Millimeter-Wave applications”, Ain Shams Engineering Journal, 15, 3, 102579, 2024, 2024/03/01/, 2090-4479, https://doi.org/10.1016/j.asej.2023.102579.