An Isolation Amplifier-Based Front-End Circuit for Grounded Capacitive Sensors

A novel front-end circuit for capacitive sensors with one terminal grounded is proposed and evaluated in this article. For the first time, it is suggested to employ an isolation amplifier (IsoAmp) in the front-end circuit of a capacitive sensor. Thanks to this IsoAmp, a floating voltage source is ge...

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Bibliographic Details
Published in:IEEE transactions on instrumentation and measurement 2024, Vol.73, p.1-10
Main Authors: Gelmini, Daniel, Haberman, Marcelo A., Ferrari, Vittorio, Spinelli, Enrique M., Reverter, Ferran
Format: Article
Language:English
Subjects:
Active shielding
Amplifiers
Cable shielding
capacitive sensor
Capacitive sensors
Electrodes
front-end circuit
grounded capacitive sensor (GCS)
Integrated circuit interconnections
Parasitics (electronics)
Remote sensing
Remote sensors
Semiconductor device measurement
sensor interface electronics
Sensors
Voltage measurement
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Summary:A novel front-end circuit for capacitive sensors with one terminal grounded is proposed and evaluated in this article. For the first time, it is suggested to employ an isolation amplifier (IsoAmp) in the front-end circuit of a capacitive sensor. Thanks to this IsoAmp, a floating voltage source is generated that appropriately excites the capacitive sensor. In addition, the concept of active shielding is applied so as to be able to measure remote sensors that are interconnected through a shielded cable. The theoretical, simulation, and experimental results reported herein demonstrate that the sensitivity of the circuit does not depend on the parasitic capacitance of the cable. However, such a parasitic does alter the offset of the input-output (I/O) characteristic mainly due to the nonidealities of the IsoAmp. In terms of linearity, the proposed front-end circuit offers remarkable values, with a maximum nonlinearity error (NLE) of around 0.1% full-scale span (FSS) in the 1-10-pF range and 0.01% FSS in the 10-100-pF range.
ISSN:0018-9456
1557-9662
DOI:10.1109/TIM.2024.3413177