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A Novel Microwave Sensor With High-Q Resonator For High Sensitivity Material Characterization

In this work, a bridge element approach based on the circular SRR configuration is proposed for accurate measurement in terms of complex permittivity and the loss tangent. It is observed that the proposed inter-connected bridge structure based on split ring resonator provides better sensitivity for...

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Bibliographic Details
Main Authors: Basri, Yosza, Ab Rashid, Siti Rosmaniza, Zakaria, Zahriladha, Shaaban, Azizah, Abd Rahim, Rosemizi, Husain, Mohd Nor
Format: Technical Report
Language:English
Published: UTeM 2019
Online Access:http://eprints.utem.edu.my/id/eprint/25458/1/A%20Novel%20Microwave%20Sensor%20With%20High-Q%20Resonator%20For%20High%20Sensitivity%20Material%20Characterization.pdf
http://eprints.utem.edu.my/id/eprint/25458/
https://plh.utem.edu.my/cgi-bin/koha/opac-detail.pl?biblionumber=117969
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Summary:In this work, a bridge element approach based on the circular SRR configuration is proposed for accurate measurement in terms of complex permittivity and the loss tangent. It is observed that the proposed inter-connected bridge structure based on split ring resonator provides better sensitivity for dielectric measurement when compared with the standard microwave SRR sensors. The sensor operating at 1 to 6 GHz frequency range with 2.5pL sample volume at a time. The mathematical derivation is generated by loading sample with a standard reference of the materials in order to develop the empirical model for the determination of complex permittivity and the loss tangent. As demonstrated by the results, the unloaded Q-factor improves more than 400 over the narrow bandwidth at operating frequency of 2.3 GHz and provides less than 5 dB of the insertion loss. The measured data of each sample are in good agreement with the corresponding reference values available in the literature having a typical average detection error of less than 2.04%. By comparison, this design has an identical performance goal and provides excellent sensing capability which can be implemented in chemical and biosensor applications.

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