High-Accuracy Complex Permittivity Characterization of Solid Materials Using Parallel Interdigital Capacitor- Based Planar Microwave Sensor

This paper presents a planar microwave sensor for the sensitive and accurate characterization of complex permittivity of solid materials. To realize the proposed sensor, the combination of a parallel interdigital capacitor and a dual wide gap resonator was etched on the ground plane and coupled with...

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Bibliographic Details
Published inIEEE sensors journal Vol. 21; no. 5; pp. 6083 - 6093
Main Authors Wang, Cong, Ali, Luqman, Meng, Fan-Yi, Adhikari, Kishor Kumar, Zhou, Zhong Liang, Wei, Yu Chen, Zou, Dan Qing, Yu, He
Format Journal Article
LanguageEnglish
Published New York IEEE 01.03.2021
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Capacitors
Complex permittivity
Electric fields
Ground plane
Microwave sensors
parallel interdigital capacitor
Permittivity
planar microwave sensor
resolution
Resonance
Resonant frequency
Sensitivity
Sensor phenomena and characterization
Sensors
solid materials
Transmission lines
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Summary:This paper presents a planar microwave sensor for the sensitive and accurate characterization of complex permittivity of solid materials. To realize the proposed sensor, the combination of a parallel interdigital capacitor and a dual wide gap resonator was etched on the ground plane and coupled with a transmission line in the top plane of a printed circuit board. The main advantage of the proposed sensor configuration lies in the generation of a high-intensity coupled resonating electric field suitable for the sensitive measurement of complex permittivity of solid materials. The high-intensity electric field enhances the coupling and field interaction, and thereby produces a high-accuracy permittivity characterization of a solid material exposed to the maximum field of the proposed sensor. Our developed microwave permittivity sensor, which characterized the complex permittivity of several materials by exploiting the measured shifts in resonance frequencies, exhibited a high sensitivity (up to 37% shift in resonance frequency for 20% change in permittivity) at least 1.5 times higher than previously reported microwave permittivity sensors. In addition, the proposed sensor exhibited 99.9% and 99.7% sensing accuracies for real and imaginary parts of permittivity, respectively, and the measurement results revealed an excellent (0.06758) and high sensitivity (67.58 MHz per unit change in real permittivity).
ISSN:1530-437X
1558-1748
DOI:10.1109/JSEN.2020.3041014