Intelligent Signal Coverage Employing Hybrid-Mode Excitation in 5G Spoof Surface Plasmon Polaritons Antennas

IF 3.5 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Open Journal of Antennas and Propagation Pub Date : 2024-03-14 DOI:10.1109/OJAP.2024.3377264

Behnam Mazdouri;Rashid Mirzavand

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Abstract

Multi-directional signal coverage utilizing simple multi-functional antenna plays a crucial role in 5G smart environment and the massive Internet of Things (IoT). The term “Multifunctionality” refers to an antenna’s ability to control and alter its radiation pattern. Spoof Surface Plasmon Polariton (SPP) antennas are considered simple and cost-effective due to their flexible one-layer configurations, making them a good candidate for smart environment. Different radiation features and signal levels in the spoof SPP antenna employing either separated or combined

$k_{-1}$

space harmonic or odd-mode are considered in this paper. Our proposed hybrid-mode antenna combines the above mentioned modes. For this purpose, a phase shift stub (PSS) is proposed for providing required phase delay. Then, the PSS is connected to a sinusoidally impedance-modulated spoof SPP antenna for hybrid-mode excitation. Our antenna supports radiation features of the mentioned modes in separate and hybrid-modes, depending on phase delay value of PSS at the operating frequencies of 26 GHz-30 GHz. Furthermore, a new design guide for odd-mode spoof SPP antennas is introduced in order to decrease side lobes’ level that are more intense in longer antennas. In order to verify the proposed structures’ performance, simulated and measured results of the reconfigurable antenna consisting of diodes and a biasing circuit are presented. The obtained measured results align well with the simulated ones.

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在 5G 欺骗表面等离子体极化子天线中采用混合模式激励实现智能信号覆盖

利用简单的多功能天线实现多方位信号覆盖，在 5G 智能环境和大规模物联网（IoT）中发挥着至关重要的作用。多功能性 "是指天线控制和改变辐射模式的能力。欺骗性表面等离子体极化子（SPP）天线因其灵活的单层配置而被认为简单且具有成本效益，是智能环境的理想选择。本文考虑了采用分离式或组合式 k_{-1}$ 空间谐波或奇数模式的欺骗 SPP 天线的不同辐射特征和信号电平。我们提出的混合模式天线结合了上述模式。为此，我们提出了一个移相存根（PSS）来提供所需的相位延迟。然后，将 PSS 连接到正弦阻抗调制的欺骗 SPP 天线，以实现混合模式激励。根据 PSS 在 26 GHz-30 GHz 工作频率下的相位延迟值，我们的天线支持上述独立模式和混合模式的辐射特性。此外，我们还为奇数模式欺骗 SPP 天线引入了新的设计指南，以降低边叶水平，因为边叶在较长的天线中更为强烈。为了验证所提出结构的性能，介绍了由二极管和偏置电路组成的可重构天线的模拟和测量结果。测量结果与模拟结果非常吻合。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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