Dualband Microstrip Elliptic Patch 1x4 MIMO Antenna Design for 5G System Device
Abstract viewed: 426 times
pdf downloaded: 315 times
Abstract
This paper presents a dual-band antenna for the 5G system communication device. The MIMO antenna can potentially boost the capacity and transmission rates to a new level in a communication system. The MIMO 1x4 elliptic circular patch is designed at 24 GHz and 27.8 GHz. From the simulated S11 results, a single patch antenna provides -16.364 dB at 24 GHz and -35.44 dB at 27.86 GHz. While for the MIMO 1x4 patch, the simulated S11 of -15.563 dB and -21.889 dB are achieved at both 24 GHz and 27.8 GHz, respectively. It has a gain value of 9.04 dBi at the 24 GHz and a gain value of 6.56 dBi at the 27.8 GHz. These gains are higher than the gain obtained with a single element.
References
[1] G. Jing, Y. Liu, X. Zhao, and L. Zhao, “Coupling Reduction of Antenna Array in 5G MIMO Frequency Band below 6GHz Based on Multi-feed Technology,” Proc. 2019 IEEE 2nd Int. Conf. Electron. Inf. Commun. Technol. ICEICT, pp. 710–712, 2019.
[2] X. T. Yuan, Z. Chen, J. Li, and T. Yuan, “A Compact Dual-Band and High-Isolation MIMO Antenna System for 5G Smartphone Applications,” 2020 IEEE MTT-S Int. Microw. Work. Ser. Adv. Mater. Process. RF THz Appl. IMWS-AMP, Proc., pp. 7–9, 2020.
[3] A. Gaya, M. H. Jamaluddin, I. Ali, and H. Mohamad, “Dual Band Circularly Polarized Rectangular Dielectric Resonator Antenna for millimeter wave 5G Applications,” APACE, IEEE Asia-Pacific Conf. Appl. Electromagn. Proc., November, pp. 25–27, 2019.
[4] M. C. Parker, G. Koczian, T. Quinlan, and S. D. Walker, “High capacity communications at 24 GHz and 60 GHz for converged 5G networking”, 20th Eur. Conf. Networks Opt. Commun. NOC, 2015.
[5] A. Dehon, “Fundamental underpinnings of reconfigurable computing architectures,” Proc. IEEE, vol. 103, no. 3, pp. 355–378, 2015.
[6] J. Tsay, J. C. Mayeda, J. Lopez, and D. Y. C. Lie, “A Highly Efficient Broadband mm-Wave 24-32.5 GHz SiGe PA for Potential 5G Applications”, Midwest Symp. Circuits Syst., vol. August, pp. 714–717, 2019.
[7] B. Feng, J. Lai, and C. Y. D. Sim, “A Building Block Assembly Dualband Dual-Polarized Antenna with Dual Wide Beamwidths for 5G Microcell Applications”, IEEE Access, vol. 8, pp. 123359–123368, 2020.
[8] GSMA, “5G Spectrum”, Public Policy Position, [Online]. Available: https://www.gsma.com/spectrum/wp-content/uploads/2016/06/GSMA-5G-Spectrum-PPP.pdf, accessed July, 2016.
[9] Here Are the Big Winners in the FCC’s 24GHz & 28GHz 5G Auctions Light Reading.” https://www.lightreading.com/mobile/5g/here-are-the-big-winners-in-the-fccs-24ghz-and-28ghz-5g-auctions/d/d-id/751903, accessed Jan 17, 2021.
[10] B. G. Hakanoglu and M. Turkmen, “An inset fed square microstrip patch antenna to improve the return loss characteristics for 5G applications”, 32nd Gen. Assem. Sci. Symp. Int. Union Radio Sci. URSI GASS, August, pp. 1–4, 2017.
[11] L. M. Ramadhan, R. P. Astuti, and B. S. Nugroho, “Simulation of design and analysis massive MIMO array microstrip rectangular patch dualband 3.5 GHz and 26 GHz for 5G communications”, Proc. IEEE Asia Pacific Conf. Wirel. Mobile, APWiMob, pp. 28–32, 2019.
[12] M. Zahid, S. Shoaib, and M. Rizwan, “Wireless Terminals”, Int. Conf. Eng. Emerg. Technol., pp. 1–4, 2019.
[13] Y. Rahayu, “New Design of 60 GHz MIMO 2x4 Patch Rectangular Antenna Array for Wireless Gigabit (Wi-Gig) Application”, Int. J. Electr. Energy Power Syst. Eng., vol. 2, no. 1, pp. 6–9, 2019.
[14] P. Liu, X. W. Zhu, Y. Zhang, X. Wang, C. Yang, and Z. H. Jiang, “Patch Antenna Loaded with Paired Shorting Pins and H-Shaped Slot for 28/38 GHz Dual-Band MIMO Applications”, IEEEAccess, vol. 8, pp. 23705–23712, 2020.
[15] T. Elhabbash and T. Skaik, “Design of dual-band dual-polarized MIMO antenna for mm-wave 5G base stations with octagonal prism structure”, IEEE 7th Palest. Int. Conf. Electr. Comput. Eng. PICECE, 2019.