Simultaneous measurement of pressure and temperature with a single FBG embedded in a polymer diaphragm

•FBG-embedded diaphragm for temperature and pressure measurements.•Simultaneous measurement of pressure and temperature with a single FBG.•The technique relies on differences between frequency responses of each parameter.•The technique leads to similar precision when compared with a system with two...

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Bibliographic Details
Published in:Optics and laser technology 2019-04, Vol.112, p.77-84
Main Authors: Leal-Junior, Arnaldo G., Díaz, Camilo A.R., Frizera, Anselmo, Marques, Carlos, Ribeiro, Moisés R.N., Pontes, Maria José
Format: Article
Language:English
Subjects:
Bragg grating
Conduction heating
Conductive heat transfer
Heat conduction
Optical sensors
Polymers
Pressure
Root-mean-square errors
Sensitivity
Temperature
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Summary:•FBG-embedded diaphragm for temperature and pressure measurements.•Simultaneous measurement of pressure and temperature with a single FBG.•The technique relies on differences between frequency responses of each parameter.•The technique leads to similar precision when compared with a system with two FBGs. This paper presents the development of a single polymer diaphragm-based fiber Bragg grating (FBG) sensor for simultaneous measurement of pressure and temperature. The FBG response is analyzed through a transient model for heat conduction and the pressure is estimated with the diaphragm and FBG strain, where the frequency difference between temperature and pressure variations were used to decouple both variables. Results show root mean squared error (RMSE) of 1.86 °C for the temperature analysis with constant pressure and 0.92 kPa for the pressure analysis with constant temperature. Experiments with variation of both temperature and pressure were conducted and the errors were higher than the ones with only temperature or pressure variations due to a residual cross-sensitivity. Therefore, the variation of both pressure and sensitivity leads to a RMSE of 3.88 °C and 5.13 kPa for temperature and pressure, respectively, which represent low errors of about 5% for both pressure and temperature.
ISSN:0030-3992
1879-2545
DOI:10.1016/j.optlastec.2018.11.013