New Electronic Interface Circuits for Humidity Measurement Based on the Current Processing Technique

Petrović, Predrag B.; Nikolić, Maria Vesna; Tatović, Mihajlo

doi:10.2478/msr-2021-0001

2021

1444.pdf (2.122Mb)

Autori

Petrović, Predrag B.
Nikolić, Maria Vesna

Tatović, Mihajlo

Članak u časopisu (Objavljena verzija)

Metapodaci

Prikaz svih podataka o dokumentu

Apstrakt

The paper describes a new electronic conditioning circuit based on the current-processing technique for accurate and reliable humidity measurement, without post-processing requirements. Pseudobrookite nanocrystalline (Fe2TiO5) thick film was used as capacitive humidity transducer in the proposed design. The interface integrated circuit was realized in TSMC 0.18 mu m CMOS technology, but commercial devices were used for practical realization. The sensing principle of the sensor was obtained by converting the information on environment humidity into a frequency variable square-wave electric current signal. The proposed solution features high linearity, insensitivity to temperature, as well as low power consumption. The sensor has a linear function with relative humidity in the range of Relative Humidity (RH) 30-90 %, error below 1.5 %, and sensitivity 8.3 x 10(14) Hz/F evaluated over the full range of changes. A fast recovery without the need of any refreshing methods was observed with a...

Ključne reči:

Humidity sensor / experimental verification / DXCCTA / current-processing technique / capacity sensor interface

Izvor:
Measurement Science Review, 2021, 21, 1, 1-10

Izdavač:

Sciendo, Warsaw

Finansiranje / projekti:

Usmerena sinteza, struktura i svojstva multifunkcionalnih materijala (RS-172057)
Inteligentne energetske mreže (RS-42009)
0-3D nanostrukture za primenu u elektronici i obnovljivim izvorima energije: sinteza, karakterizacija i procesiranje (RS-45007)

DOI: 10.2478/msr-2021-0001

ISSN: 1335-8871

WoS: 000655290100001

Scopus: 2-s2.0-85104297913

[ Google Scholar ]


	2

TY  - JOUR
AU  - Petrović, Predrag B.
AU  - Nikolić, Maria Vesna
AU  - Tatović, Mihajlo
PY  - 2021
UR  - http://rimsi.imsi.bg.ac.rs/handle/123456789/1447
AB  - The paper describes a new electronic conditioning circuit based on the current-processing technique for accurate and reliable humidity measurement, without post-processing requirements. Pseudobrookite nanocrystalline (Fe2TiO5) thick film was used as capacitive humidity transducer in the proposed design. The interface integrated circuit was realized in TSMC 0.18 mu m CMOS technology, but commercial devices were used for practical realization. The sensing principle of the sensor was obtained by converting the information on environment humidity into a frequency variable square-wave electric current signal. The proposed solution features high linearity, insensitivity to temperature, as well as low power consumption. The sensor has a linear function with relative humidity in the range of Relative Humidity (RH) 30-90 %, error below 1.5 %, and sensitivity 8.3 x 10(14) Hz/F evaluated over the full range of changes. A fast recovery without the need of any refreshing methods was observed with a change in RH. The total power dissipation of readout circuitry was 1 mW.
PB  - Sciendo, Warsaw
T2  - Measurement Science Review
T1  - New Electronic Interface Circuits for Humidity Measurement Based on the Current Processing Technique
EP  - 10
IS  - 1
SP  - 1
VL  - 21
DO  - 10.2478/msr-2021-0001
ER  -

@article{
author = "Petrović, Predrag B. and Nikolić, Maria Vesna and Tatović, Mihajlo",
year = "2021",
abstract = "The paper describes a new electronic conditioning circuit based on the current-processing technique for accurate and reliable humidity measurement, without post-processing requirements. Pseudobrookite nanocrystalline (Fe2TiO5) thick film was used as capacitive humidity transducer in the proposed design. The interface integrated circuit was realized in TSMC 0.18 mu m CMOS technology, but commercial devices were used for practical realization. The sensing principle of the sensor was obtained by converting the information on environment humidity into a frequency variable square-wave electric current signal. The proposed solution features high linearity, insensitivity to temperature, as well as low power consumption. The sensor has a linear function with relative humidity in the range of Relative Humidity (RH) 30-90 %, error below 1.5 %, and sensitivity 8.3 x 10(14) Hz/F evaluated over the full range of changes. A fast recovery without the need of any refreshing methods was observed with a change in RH. The total power dissipation of readout circuitry was 1 mW.",
publisher = "Sciendo, Warsaw",
journal = "Measurement Science Review",
title = "New Electronic Interface Circuits for Humidity Measurement Based on the Current Processing Technique",
pages = "10-1",
number = "1",
volume = "21",
doi = "10.2478/msr-2021-0001"
}

Petrović, P. B., Nikolić, M. V.,& Tatović, M.. (2021). New Electronic Interface Circuits for Humidity Measurement Based on the Current Processing Technique. in Measurement Science Review
Sciendo, Warsaw., 21(1), 1-10.
https://doi.org/10.2478/msr-2021-0001

Petrović PB, Nikolić MV, Tatović M. New Electronic Interface Circuits for Humidity Measurement Based on the Current Processing Technique. in Measurement Science Review. 2021;21(1):1-10.
doi:10.2478/msr-2021-0001 .

Petrović, Predrag B., Nikolić, Maria Vesna, Tatović, Mihajlo, "New Electronic Interface Circuits for Humidity Measurement Based on the Current Processing Technique" in Measurement Science Review, 21, no. 1 (2021):1-10,
https://doi.org/10.2478/msr-2021-0001 . .