This paper discusses the development and characterization of 3D-printed dielectric image lines for subTHz chip-to-chip interconnects. The use of conductive copper substrates enhances routing and mechanical stability, resulting in minimal losses below 0.35 dB/cm. The study focuses on the design, fabrication, and measurement setup of these dielectric image lines to achieve broadband matching over the frequency band from 140 GHz to 220 GHz.
Dielectric image lines offer low-loss transmission options compared to conventional planar transmission lines, enabling longer off-chip connections at subTHz frequencies. The paper emphasizes the importance of dielectric waveguides in high-performance imaging systems and communication networks. By utilizing additive manufacturing (3D printing), these dielectric image lines become lightweight, cost-effective, and flexible solutions for subTHz distribution networks.
The research delves into the topology of image lines based on conventional dielectric waveguides with additional conductive surfaces for improved guidance and stability. Mode converters are designed to facilitate easy integration and characterization within a waveguide system. Measurement setups using frequency converters enable thorough characterization of transmission properties, showcasing excellent matching and low insertion losses.
Furthermore, the study investigates the impact of bending radii on transmission behavior, emphasizing that radii below 30 mm lead to parasitic radiation effects. Results show that deviations in geometry have minor impacts on transmission quality compared to factors like taper accuracy and surface quality. Overall, the research highlights the potential of 3D-printed dielectric image lines for subTHz applications.
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by Leonhard Hah... о arxiv.org 03-07-2024
https://arxiv.org/pdf/2403.03657.pdfГлибші Запити