Mm-Wave Beam Steering Antenna Arrays Using Microfluidically Reconfigurable Beamforming Networks

IF 6.9 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE journal of microwaves Pub Date : 2023-10-04 DOI:10.1109/JMW.2023.3312341
Jonas Mendoza;Gokhan Mumcu
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Abstract

A microfluidically reconfigurable beamforming network is introduced for beam steering mm-wave antenna arrays. The beamforming network consists of a selectively metallized plate (SMP) that is encapsulated within a microfluidic channel in close proximity to multiple microstrip lines. Metallization traces of the SMP capacitively loads the microstrip lines to realize multiple slow-wave phase shifters. Varying the position of SMP over the lines creates variable phase shifts of the device. Strategically designing the SMP traces on each microstrip line leads to progressive phase shifting, resulting in operation with a single actuator. The manuscript presents a circuit model to facilitate the design of the beamforming network and presents experimental verification with a four-element antenna array operating at 28.5 GHz. The array exhibits continuous beam steering capability within $\pm {30}^{\circ }$ when its SMP is actuated within its 100 to +100 $\mu$ m displacement range. The beam steering speed from $-{30}^{\circ }$ to $+{30}^{\circ }$ is 75 ms. The realized gain is 5.6 dBi at broadside and 6.8 dBi at ${30}^{\circ }$ scan angle corresponding to a radiation efficiency of 64% (including all losses in the system). The device is expected to handle 10 W of continuous RF power
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基于微流控可重构波束形成网络的毫米波波束控制天线阵列
介绍了一种用于波束控制毫米波天线阵列的微流控可重构波束形成网络。波束成形网络由选择性金属化板(SMP)组成,该板被封装在紧邻多条微带线的微流体通道内。SMP的金属化迹线电容性地加载微带线以实现多个慢波移相器。改变SMP在线路上的位置会产生器件的可变相移。在每条微带线上战略性地设计SMP迹线会导致渐进的相移,从而导致使用单个致动器进行操作。该手稿提出了一个电路模型,以便于波束形成网络的设计,并提出了在28.5GHz下工作的四元天线阵列的实验验证。当SMP在其100至+100$\mu$m的位移范围内致动时,阵列在$\pm{30}^{\circ}$范围内表现出连续波束操纵能力。从$-{30}^{\circ}$到$+{30}^的波束转向速度为75ms。实现的增益在宽侧为5.6dBi,在${30}^2扫描角为6.8dBi,对应于64%的辐射效率(包括系统中的所有损耗)。该设备预计可处理10 W的连续射频功率
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CiteScore
10.70
自引率
0.00%
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0
审稿时长
8 weeks
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Front Cover Table of Contents Introduction to the Fall 2024 Issue IEEE Microwave Theory and Technology Society Information Over-the-Air Phase Noise Spectral Density Measurement for FMCW Radar Sensors
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