Bandwidth and Center Frequency Reconfigurable Waveguide Filter Based on Liquid Crystal Technology

This paper presents for the first time a fully electronically reconfigurable waveguide filter tunable in bandwidth and center frequency based on liquid crystal (LC) technology. A continuously reconfigurable two pole bandpass filter is designed and characterized in the Ka-band at 30 \,\mathrm{GHz}. T...

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Bibliographic Details
Published in:IEEE journal of microwaves 2022-01, Vol.2 (1), p.134-144
Main Authors: Kamrath, Fynn, Polat, Ersin, Matic, Stipo, Schuster, Christian, Miek, Daniel, Tesmer, Henning, Boe, Patrick, Wang, Dongwei, Jakoby, Rolf, Maune, Holger, Hoft, Michael
Format: Article
Language:English
Subjects:
Bandwidth
Couplings
Inverters
K-band
liquid crystals
Microwave filter
millimeter wave communication
Permittivity
Resonant frequency
Resonators
tunable circuits and devices
Tuning
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Summary:This paper presents for the first time a fully electronically reconfigurable waveguide filter tunable in bandwidth and center frequency based on liquid crystal (LC) technology. A continuously reconfigurable two pole bandpass filter is designed and characterized in the Ka-band at 30 \,\mathrm{GHz}. To be able to tune both center frequency and bandwidth independently, the resonators and coupling structures are filled with LC as tunable material. Hence, the filter's center frequency and coupling strengths can be tuned and, furthermore, tuning with constant filter characteristic is possible. To tune the LC, a novel two-layer electrode design for waveguide structures is presented, which is simple to integrate and provides a high tuning efficiency with low insertion loss. By applying different bias configurations, the LC's effective permittivity can be varied, and therefore, also the resonators' electrical lengths. The presented two pole filter can adapt its center frequency from 29.8 \,\mathrm{GHz}\,{\rm to}\, 30.7 \,\mathrm{GHz} with a maximum 3 \,{\rm dB} bandwidth variation from 660 \,\mathrm{MHz}\,{\rm to}\, 870 \,\mathrm{MHz}. The measurements are carried out with bias voltages up to \pm250 \,\mathrm{V}.
ISSN:2692-8388
2692-8388
DOI:10.1109/JMW.2021.3115244