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Liquid Crystal Mixed Beam-Switching and Beam-Steering Network in Hybrid Metallic and Dielectric Waveguide Technology

Jost, Matthias (2018)
Liquid Crystal Mixed Beam-Switching and Beam-Steering Network in Hybrid Metallic and Dielectric Waveguide Technology.
Book, Primary publication

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Item Type: Book
Type of entry: Primary publication
Title: Liquid Crystal Mixed Beam-Switching and Beam-Steering Network in Hybrid Metallic and Dielectric Waveguide Technology
Language: English
Referees: Jakoby, Prof. Rolf ; Ferrari, Prof. Philippe
Date: 2018
Place of Publication: Darmstadt
Publisher: Shaker Verlag
Date of oral examination: 26 April 2018
Corresponding Links:
Abstract:

Future communication systems at W-band are demanding highly directive antenna systems with beam-steering capability. For the hardware implementation of analogue beam-steering at millimetre waves, the microwave liquid crystal (LC) technology is ideally suited. It takes advantage of specifically synthesised LCs for microwaves in combination with appropriate device and biasing concepts, where the orientation of the LC, and therefore, its effective permittivity can be continuously tuned. It has low dielectric losses above 10GHz with a decreasing trend with increasing frequency. To exploit these unique characteristics, the focus of this scientific work is set for the first time on the investigation of an LC-based network with mixed discrete beam-switching and continuous beam-steering capability between the switching states for high-gain antennas at W-band. It consists of a Butler matrix combined with continuously tuneable phase shifters and a novel type of RF switch, an interference-based Single-Pole n-Throw (SPnT). The interference principle of the SPnT allows a continuously adjustable power splitting ratio, and hence, the generation of multiple beams.

Different technologies are investigated for the realisation of this mixed network. Due to its high level of integrability and compact designs, the standard low temperature co-fired ceramic technology is examined, however, for a first proof-of-concept at Ka-band only. For W-band, two low-loss technologies are investigated: tuneable metallic and dielectric waveguides. While metallic waveguides are well suited for the realisation of low-loss non-tuneable feeding networks, dielectric waveguides are better suited for the realisation of tuneable LC components at (sub)millimetre waves, since no metallic boundaries are limiting the integration of an electrical biasing network. As non-tuneable core part, a Butler matrix with an average insertion loss of 3.5 dB at 102 GHz is realised, which is based on a novel multifunctional crossover design, allowing a miniaturised in-plane realisation of the overall mixed network. As key component for tuning of the mixed beam-switching and beam-steering network, a step-index dielectric waveguide phase shifter is presented. With a phase shifter figure-of-merit of 100 °/dB at 102 GHz, this fully electrically biased phase shifter is going far beyond the state-of-the-art for electrically tuneableW-band phase shifter.

To stay on the same technology platform and to allow an in-plane realisation from the input port up to the radiating elements, the interference-based SPnTs are additionally investigated by a hybrid implementation of metallic and dielectric waveguides. It exhibits an insertion loss of 3dB, while providing an isolation of 27 dB. Hence, this hybrid metallic and dielectric waveguide technology reveals a high potential not only for the presented LC-based mixed beam-switching and beam-steering network, but also for LC-tuned continuous beam-steering networks at frequencies above 100 GHz, since low-loss metallic waveguide feeding networks can be generally combined with high-performance tuneable dielectric waveguides.

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Alternative AbstractLanguage
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URN: urn:nbn:de:tuda-tuprints-76590
Classification DDC: 600 Technology, medicine, applied sciences > 620 Engineering and machine engineering
Divisions: 18 Department of Electrical Engineering and Information Technology > Institute for Microwave Engineering and Photonics (IMP) > Microwave Engineering
18 Department of Electrical Engineering and Information Technology > Institute for Microwave Engineering and Photonics (IMP)
Date Deposited: 29 Aug 2018 11:29
Last Modified: 09 Jul 2020 02:12
URI: https://tuprints.ulb.tu-darmstadt.de/id/eprint/7659
PPN: 435357778
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