Design and Characterization of Line-Waves Waveguides for Microwave Applications

IF 3.5 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Open Journal of Antennas and Propagation Pub Date : 2024-11-26 DOI:10.1109/OJAP.2024.3506876

Alessio Monti;Stefano Vellucci;Mirko Barbuto;Valentina Verri;Francesco Vernì;Claudio Massagrande;Davide Ramaccia;Michela Longhi;Zahra Hamzavi-Zarghani;Luca Stefanini;Alessandro Toscano;Filiberto Bilotti

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Abstract

Line-waves are one-dimensional modes propagating at the interface between two planar complementary surfaces, characterized by tight transversal confinement of the field. Despite their unique guiding properties, their use in real microwave devices is still in the early stages, lacking a comprehensive design procedure and comparative analysis with conventional guiding structures. To fill this gap, here we report a simple and straightforward workflow for designing waveguides supporting 1D modes propagation. The design is based on the analytical relations existing between the surface impedance of the propagating modes and the sheet impedance of the metasurfaces, which allow quick retrieval of the geometrical parameters of the complementary metasurfaces sustaining the line-wave propagation. This approach is used to design several waveguiding layouts and compare their transmission performance through full-wave simulations accounting for dielectric and ohmic losses. Finally, experimental results for some selected designs in the microwave regime are provided, and a thoughtful comparison between a line-wave waveguide and an equivalent microstrip transmission line is carried out to assess the suitability of these devices for efficient high-frequency waveguiding.

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微波应用线波波导的设计与特性

线波是在两个平面互补面之间的界面上传播的一维模式，其特征是场的紧密横向限制。尽管具有独特的导向特性，但其在实际微波器件中的应用仍处于初级阶段，缺乏与传统导向结构的综合设计过程和比较分析。为了填补这一空白，我们在这里报告了一个简单而直接的工作流程，用于设计支持1D模式传播的波导。该设计基于传播模式的表面阻抗与超表面的片阻抗之间存在的解析关系，可以快速检索维持线波传播的互补超表面的几何参数。该方法用于设计几种波导布局，并通过考虑介电损耗和欧姆损耗的全波模拟来比较它们的传输性能。最后，给出了在微波环境下一些选定设计的实验结果，并对线波波导和等效微带传输线进行了仔细的比较，以评估这些器件用于高效高频波导的适用性。

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