High isolation 16-port massive MIMO antenna based negative index metamaterial for 5G mm-wave applications-Reference-Cited by-同舟云学术

High isolation 16-port massive MIMO antenna based negative index metamaterial for 5G mm-wave applications

Published:2024-01-02 Issue:1 Volume:14 Page:
ISSN:2045-2322
Container-title:Scientific Reports
language:en
Short-container-title:Sci Rep

Author:

Musaed Alya Ali,Al-Bawri Samir Salem,Abdulkawi Wazie M.,Aljaloud Khaled,Yusoff Zubaida,Islam Mohammad Tariqul

Abstract

AbstractA 16-port massive Multiple-Input-Multiple-Output (mMIMO) antenna system featuring a high gain and efficiency is proposed for millimeter-wave applications. The antenna system consists of 64 elements with a total size of 17 λo × 2.5λo, concerning the lowest frequency. Each 2 × 2 (radiating patch) subarray is designed to operate within the 25.5–29 GHz frequency range. The antenna's performance in terms of isolation, gain, and efficiency has been significantly improved by utilizing the proposed unique double and epsilon negative (DNG/ENG) metamaterials. The array elements are positioned on top of a Rogers RT5880 substrate, with ENG metamaterial unit cells interposed in between to mitigate coupling effects. Additionally, the DNG metamaterial reflector is positioned at the rear of the antenna to boost the gain. As a result, the metamaterial-based mMIMO antenna offers lower measured isolation reaching 25 dB, a maximum gain of 20 dBi and an efficiency of up to 99%. To further analyze the performance of the MIMO antenna, the diversity gain and enveloped correlation coefficient are discussed in relation to the MIMO parameters.

Publisher

Springer Science and Business Media LLC

Link

https://www.nature.com/articles/s41598-023-50544-z.pdf

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5. Author Correction: High isolation 16-port massive MIMO antenna based negative index metamaterial for 5G mm-wave applications;Scientific Reports;2024-04-25