Abstract
A low-profile Multiple Input Multiple Output (MIMO) antenna showing dual polarization, low mutual coupling, and acceptable diversity gain is presented by this paper. The antenna introduces the requirements of fifth generation (5G) and the satellite communications. A horizontally (4.8–31 GHz) and vertically polarized (7.6–37 GHz) modified antipodal Vivaldi antennas are simulated, fabricated, and integrated, and then their characteristics are examined. An ultra-wideband (UWB) at working bandwidths of 3.7–3.85 GHz and 5–40 GHz are achieved. Low mutual coupling of less than −22 dB is achieved after loading the antenna with cross-curves, staircase meander line, and integration of the metamaterial elements. The antennas are designed on a denim textile substrate with = 1.4 and h = 0.5 mm. A conductive textile called ShieldIt is utilized as conductor with conductivity of 1.8 × 104. After optimizing the proposed UWB-MIMO antenna’s characteristics, it is increased to four elements positioned at the four corners of a denim textile substrate to be employed as a UWB-MIMO antenna for handset communications, 5G, Ka and Ku band, and satellite communications (X-band). The proposed eight port UWB-MIMO antenna has a maximum gain of 10.7 dBi, 98% radiation efficiency, less than 0.01 ECC, and acceptable diversity gain. Afterwards, the eight-ports antenna performance is examined on a simulated real voxel hand and chest. Then, it is evaluated and compared on physical hand and chest of body. Evidently, the simulated and measured results show good agreement between them. The proposed UWB-MIMO antenna offers a compact and flexible design, which is suitably wearable for 5G and satellite communications applications.
Highlights
The fundamental properties of a suggested prototype comprising a modified antipodal Vivaldi (MAVA) patch integrated with ten MTM components are studied, and its capacity to function as a UWB-Multiple Input Multiple Output (MIMO) transceiver element for 5G and satellite communications is demonstrated
A UWB-MIMO antenna based on MTM was assembled for research application within
The MAVA is used in the proposed metamaterial-integrated MIMO antenna to achieve dual-polarization and polarization diversity
Summary
There are several difficulties in designing antennas when they encounter body, such as the impacts of high loss due to the high relative permittivity of human tissues which degrade the wearable antenna performance [3] They must be properly constructed to retain. Mutual coupling between each antenna element is unavoidable in a MIMO system, and it has a detrimental impact on the antenna’s properties It degrades pattern correlation and radiation efficiency. The most frequent decoupling structures for plane monopole MIMO antennas are parasitic components and defective grounds [29,30] Another method for creating polarization and pattern diversity in UWB-MIMO antennas is to utilize slot antennas with orthogonal feeding [31,32].
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