5G和机器人应用的新型空心基板集成波导

Giorgos Savvides, Nattapong Duangrit, N. Chudpooti, P. Akkaraekthalin, I. Robertson, N. Somjit
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引用次数: 0

摘要

本文提出了一种新型的空心基板集成波导(HSIW),该波导采用减法和增材制造技术构建。具体来说,它利用聚合物喷射方法打印丙烯腈-丁二烯-苯乙烯(ABS)介质基板和水激光切割系统来生产光滑的铜片作为HSIW的顶部和底部外壳。此外,制造过程是利用市售的预制过孔的机械通孔电镀,消除了其他SIW设计中进行过孔制造和金属化过程的成本和复杂性。拟议的波导涵盖了5G新的无线电频段,特别是从21 GHz到31 GHz。在整个工作频率范围内,它的模拟衰减常数和测量衰减常数分别为0.636 Np/m和1.56 Np/m,是迄今为止报道的最低值之一。本文所提出的高阶集成电路,在紧凑性、制造成本和性能方面,可以与其他先进的设计相比较。设计的HSIW可以与其他平面电路集成,并可用于构建5G,机器人和物联网应用的天线或滤波器等功能设备。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Novel Hollow Substrate Integrated Waveguide for 5G and Robotic Applications
This paper presents, a novel design of a Hollow Substrate Integrated Waveguide (HSIW), that is built by using both Subtractive and Additive Manufacturing technologies. Specifically, it utilizes Polymer jetting method to print an Acrylonitrile butadiene styrene (ABS) dielectric substrate and a water laser cutter system to produce smooth copper sheets as the top and bottom enclosures of the HSIW. Also, the fabrication process is utilizing mechanical through hole plating of commercially available prefabricated vias, eliminating the cost and complexity of performing vias fabrication and metallization process as in other SIW designs. The proposed waveguide covers 5G new radio frequency bands, specifically from 21 GHz to 31 GHz. It has a simulated and a measured attenuation constant of 0.636 Np/m and 1.56 Np/m respectively, for the whole operating frequency range and is among the lowest reported values to date. The proposed HSIW of this paper, can be compared with other state- of-the-art designs in terms of compactness, manufacturing cost and performance. The designed HSIW can be integrated with other planar circuits and can be used to build functional devices such as antennas or filters for 5G, robotics and IoT applications.
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