Graphene-based frequency agile isolation enhancement mechanism for MIMO antenna in terahertz regime

太赫兹辐射 分集增益 多输入多输出 解耦(概率) 分集方案 天线分集 辐射模式 反射系数 物理 光学 透射系数 偶极子天线 光电子学 天线(收音机) 电子工程 传输(电信) 电信 计算机科学 衰退 工程类 控制工程 解码方法 波束赋形
作者
Naveen Kumar Maurya,Sadhana Kumari,Prakash Pareek,Lokendra Singh
出处
期刊:Nano Communication Networks [Elsevier BV]
卷期号:35: 100436-100436 被引量:45
标识
DOI:10.1016/j.nancom.2023.100436
摘要

This paper presents a graphene-based frequency tunable isolation enhancement mechanism for terahertz (THz) MIMO antenna. The presented simple and compact decoupling method could also be employed for any THz device. An isolation enhancement of about 30.41 dB has been achieved at the frequency of operation. The decoupling structure has the ability to suppress mutual coupling caused by any radiation mode of the MIMO element. The change of 0.2 eV (i.e., from 0.5 to 0.7 eV) in chemical potential (μc) provides a frequency tunability of about one THz in the transmission coefficient of the decoupling structure. The proposed decoupling technique is applied to the slot ring-based dual-polarized MIMO/diversity antenna. The diversity antenna provides a bandwidth (BW) of 0.83 THz (5.68–6.51 THz) with isolation of 47.56 dB at resonant frequency (6 THz). The gain and efficiency of the proposed diversity antenna at 6 THz are better than 3.99 dBi and 90.17%, respectively. The envelope correlation coefficient (ECC) calculated from far-field and diversity gain (DG) are 4.818 × 10 −7 and 10, respectively. Total active reflection coefficient (TARC) is found to be less than -10 dB for different values of input feeding phase θ and the mean effective gain ratio (MEGi/MEGj) is close to one, which confirms the antenna’s applicability for diversity application in multipath rich wireless channels.

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