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Designs, developments, challenges, and fabrication materials for MIMO antennas with various 5G and 6G applications: a review

Published online by Cambridge University Press:  28 November 2024

Karrar Shakir Muttair*
Affiliation:
Department of Computer Engineering Techniques, Electrical Engineering Technical College, Middle Technical University, Baghdad, Iraq Nanotechnology and Advanced Materials Research Unit, Faculty of Engineering, University of Kufa, Najaf, Iraq
Oras Ahmed Shareef
Affiliation:
Department of Computer Engineering Techniques, Electrical Engineering Technical College, Middle Technical University, Baghdad, Iraq Department of Medical Devices Technical Engineering, Al-Ayen Iraqi University, AUIQ, Thi-Qar, Iraq
Hazeem Baqir Taher
Affiliation:
Department of Computer Science, College of Education for Pure Sciences, Thi-Qar University, Thi-Qar, Iraq
*
Corresponding author: Karrar Shakir Muttair; Email: karrars.alnomani@uokufa.edu.iq
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Abstract

The rapid expansion of digital media platforms and their growing user base in the wireless industry necessitate communication systems to provide information at high speeds with reliable connections. Therefore, wireless communication systems with a single antenna cannot accomplish these requirements. Consequently, the access and utilization of multi-input multi-output (MIMO) antennas are becoming more common in contemporary high-speed transmission systems. This article covers the fundamentals of MIMO antenna operation, the metrics for MIMO antenna performance parameters, and the design methodologies for specifying the three most commonly used antennas (two-port, quad-port, and eight-port). Additionally, it discusses their ability to improve channel capacity significantly. It focuses on designing MIMO antennas with ultra-wideband (UWB) for 5G systems operating between 1 and 27 GHz and millimeter-wave (mmWave) bands from 30 to 100 GHz. This article is valuable for researchers interested in developing MIMO antennas for diverse applications. It compiles advanced methods related to materials, advancements, challenges, and state-of-the-art technologies used in the design of high-performance MIMO antennas. We concluded that antennas that operate at mmWave frequencies have small dimensions and suffer from isolation problems in the MIMO formation. In contrast, antennas operating below 6 GHz are large and do not suffer from isolation problems.

Information

Type
Review Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press in association with The European Microwave Association.
Figure 0

Figure 1. Frequency bands assigned to 5G and 6G wireless technologies.

Figure 1

Figure 2. A schematic of multiband MIMO antenna designs.

Figure 2

Figure 3. Antenna structural shapes on both sides: (a) simulation design; (b) realistic manufacturing design [23].

Figure 3

Figure 4. The reflection coefficient parameter of the antenna in simulation and realistic measurements. (a) The simulation side; (b) The simulation and practical side of S11; (c) The simulation and practical side of S22 [23].

Figure 4

Table 1. An overview of the latest research into the advancement of wideband two-port antennas

Figure 5

Figure 5. The fabrication geometry of the proposed antenna is (a) front view and (b) back view [24].

Figure 6

Figure 6. The antenna performance curves for (a) reflection coefficient (S11 and S22) and isolation (S12 and S21), (b) ECC, and (c) DG [24].

Figure 7

Table 2. A detailed comparison and summary of recent research papers introducing dual-port antennas in the mmWave bands

Figure 8

Figure 7. The S-parameter curves versus the different frequencies [66].

Figure 9

Figure 8. (a) Prototype antenna with four ports on the front; (b) antenna bending model at 20 mm; and (c) antenna performance measurement using a vector network analyzer device [66].

Figure 10

Figure 9. An antenna manufacturing prototype (a) on the front side and (b) on the back side [67].

Figure 11

Figure 10. The basic parameters to determine the efficiency of the proposed antenna in reference [67] are (a) gain curves, (b) ECC curves, (c) DG curves, and (d) CCL curves.

Figure 12

Figure 11. The return loss curves versus the various frequencies for (a) simulation side curves and (b) comparisons between simulation side curves and manufacturing measurements [68].

Figure 13

Figure 12. The design of the proposed antenna shapes (a) CST simulation, (b) practical design on the front side, and (c) practical design on the back side [68].

Figure 14

Table 3. A summary of recent studies on the design of a four-port antenna that operates at frequencies below 27 GHz

Figure 15

Figure 13. Antenna designs for simulation and manufacturing: (a) simulation front side, (b) simulation back side, (c) fabrication front side, and (d) fabrication back side [69].

Figure 16

Figure 14. Curves of S-parameters versus different frequencies from 2 to 12 GHz (a) return loss curves and (b) isolation curves between ports [69].

Figure 17

Figure 15. Practical aspects of the proposed antenna include (a) manufacturing the antenna and (b) measuring the antenna’s performance using an analysis device (Rohde & Schwarz) [70].

Figure 18

Figure 16. (a) S-parameter curves for the simulation and measurement sides, and (b) isolation curves between ports [70].

Figure 19

Table 4. A summary of the most recent research on quad-port antennas designed for mmWave frequency bands

Figure 20

Figure 17. The structural manufacturing design of the proposed antenna for (a) the front face and (b) the back face [120].

Figure 21

Figure 18. Antenna performance measurement curves for (a) and (b) reflection coefficient and (c) transmission coefficient [120].

Figure 22

Figure 19. The complementary results achieved by the antenna are (a) gain curves for both sides of CST simulation and actual measurements, and (b) total efficiency curves for simulation and manufacturing [120].

Figure 23

Figure 20. A geometric design of the proposed octa-port MIMO antenna using the HFSS simulation program [121].

Figure 24

Figure 21. The fabrication geometry of the proposed MIMO antenna for (a) the front view and (b) the back view [121].

Figure 25

Figure 22. (a) The reflection coefficients for the simulation and fabrication aspects, and (b) the mutual coupling between all ports [121].

Figure 26

Figure 23. Overall antenna efficiency for all simulations and fabrication measurements [121].

Figure 27

Table 5. A detailed comparison of the latest articles proposing eight-port antennas operates at frequencies sub-27 GHz

Figure 28

Table 6. A comparison of recent research on eight-port or more antennas relying on mmWave bands

Figure 29

Figure 24. The proposed antenna design stages are (a) the first stage, (b) the second stage, and (c) the third stage.

Figure 30

Figure 25. The primary challenges for designers in creating multiband MIMO antennas.