Abstract
This article presents, for the first time, new design and fabrication techniques for Hollow Substrate Integrated Waveguides (HSIWs), demonstrated in the nominal frequency from 21 to 31 GHz, for use in wireless communication applications such as 5G, IoT and robotics. The design and fabrication techniques introduced in this paper feature: 1) the use of low-cost rapid prototyping additive manufacturing based on polymer jetting (PJ), and 2) the use of commercially available through-substrate copper via transitions. In contrast to the conventional SIW designs and fabrications, this new approach does not rely on through-substrate via fabrication, hence avoiding some difficult manufacturing steps, such as through-substrate etching, via formation and via metallization, which are considered complex and expensive to implement. The 3D printed HSIWs in this article can achieve a propagation loss of lower than 1.56 Np/m (13.55 dB/m), which is considered one of the results with the lowest propagation loss achieved to date, when compared to the state-of-the-art.
Highlights
Transmission lines are crucially important in many high frequency applications and are used in RF, microwave, millimeter-wave and terahertz systems
MEASUREMENT RESULTS All three HSIW prototypes were attached with relaunchable SOUTHWEST 2.4-mm coaxial connectors mounted on both sides of the microstrip feed lines
The measured reflection coefficient, S11, of the 3D-printed HSIW was lower than −10 dB over the operational band of 21–31 GHz while the S21 is better than −3.56 dB for the entire selected band
Summary
Transmission lines are crucially important in many high frequency applications and are used in RF, microwave, millimeter-wave (mmWave) and terahertz systems.
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