Study of the interdigital electrode sensor at resonance frequency during water transition

This paper uses the co-planar interdigital electrode (IDE) sensor to measure water level. The researchers generally characterize the interdigital electrode sensor as a fringe field capacitor sensor developed on the printed circuit board and utilize the capacitor sensor's properties for liquid-l...

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Bibliographic Details
Published in:Journal of instrumentation 2024-04, Vol.19 (4), p.P04040
Main Authors: Ranjan, Prem, Dash, Dinesh Kumar, Maharana, Rashmi Ranjan, Chowdhury, Atanu
Format: Article
Language:English
Subjects:
Analogue electronic circuits
Circuit boards
Electrodes
Electronic detector readout concepts (gas, liquid)
Liquid detectors
Resonance
Resonant Detectors
RLC circuits
Sensors
Standard error
Water levels
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Summary:This paper uses the co-planar interdigital electrode (IDE) sensor to measure water level. The researchers generally characterize the interdigital electrode sensor as a fringe field capacitor sensor developed on the printed circuit board and utilize the capacitor sensor's properties for liquid-level measurement. The interdigital electrode sensors illustrate more than one resonance at the higher frequencies, and in this study, the first resonance frequency f r -has been utilized for the water level measurement. Three water types are examined here: distilled, tap, and river. The study assesses that with the transition of water, the permittivity between the electrodes is changed and, it leads to a change in capacitance hence, the change in resonance frequency was observed. The proposed sensor can be represented by the lumped element equivalent series RLC circuit. The developed IDE sensor has good repeatability, small variability, and small hysteresis error. The maximum standard error for distilled, tap, and river water are 0.02833, 0.02503, and 0.02618, respectively, and the hysteresis error is less than 1.903% of full-scale output variation. The maximum error for the f r estimation is about ±2 Hz.
ISSN:1748-0221
1748-0221
DOI:10.1088/1748-0221/19/04/P04040