Title :
Fiber-Optic Temperature Sensor Using a Fabry–Pérot Cavity Filled With Gas of Variable Pressure
Author :
Yujie Lu ; Ming Han ; Jiajun Tian
Author_Institution :
Dept. of Electr. Eng., Univ. of Nebraska-Lincoln, Lincoln, NE, USA
Abstract :
We report a high-temperature fiber-optic sensor based on measuring the spectral fringes of a Fabry-Pérot (FP) cavity on a microstructure fiber (MF) when the gas pressure in the cavity is varied through the holes in the MF. Theoretical analysis shows that the absolute temperature can be deduced from the slope of the spectral shift versus pressure curve, which requires no calibration and is insensitive to the FP cavity length variations. For demonstration, we fabricated a miniature sensor whose FP cavity is formed by sandwiching a fuse-silica tube between a side-hole MF and a solid-core fiber. Using the holes in the MF as gas channels, the pressure in the FP cavity is controlled. The sensor was tested for operation above 1000°C. Strain-insensitive temperature measurement was demonstrated at ambient temperature for a strain range up to 3600 με.
Keywords :
fibre optic sensors; holey fibres; optical fibre fabrication; optical fibre testing; silicon compounds; spectral line shift; temperature measurement; temperature sensors; Fabry-Perot cavity length variation; SiO2; fiber-optic temperature sensor; fuse-silica tube; gas channels; high-temperature fiber-optic sensor; side-hole microstructure fiber; solid-core fiber; spectral fringes; spectral shift; strain-insensitive temperature measurement; variable pressure gas; Cavity resonators; Fitting; Optical fiber sensors; Strain; Temperature measurement; Temperature sensors; Fabry–Pérot interferometer; Fiber-optic sensors; microstructure fiber; temperature measurement;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2014.2304297
