Title :
Interferometric interrogation of in-fiber Bragg grating sensors without mechanical path length scanning
Author :
Murphy, Dominic F. ; Flavin, Dónal A. ; McBride, Roy ; Jones, Julian D C
Author_Institution :
Dept. of Phys. & Quantitative Sci., Waterford Inst. of Technol., Ireland
fDate :
7/1/2001 12:00:00 AM
Abstract :
We report the interrogation of a fiber Bragg grating (FBG) using an interferometer with a tilted mirror such that the optical path difference is a function of position on an array detector. Absolute measurements of mean resonant wavelength from the phase of the analytic signal of the spatial interferogram are determined, and a technique based on using a reference laser to compensate for performance degrading effects otherwise associated with spatially scanned interferometers is introduced. These measurements are not critically dependent on the accurate location of zero phase position. We have applied the technique to the absolute measurement of temperature-induced shifts in the grating resonant wavelength. A resolution of 0.025 nm for a spatially scanned optical path delay of only 200 μm was achieved. The technique has the potential for higher resolutions and for multiplexing
Keywords :
Bragg gratings; CCD image sensors; demodulation; fibre optic sensors; mirrors; optical beam splitters; absolute measurement; absolute measurements; accurate location; array detector; grating resonant wavelength; in-fiber Bragg grating sensors; interferometric interrogation; mean resonant wavelength; multiplexing; optical path difference; performance degrading effects; reference laser; spatial interferogram; spatially scanned interferometers; spatially scanned optical path delay; temperature-induced shifts; tilted mirror; zero phase position; Bragg gratings; Fiber gratings; Mirrors; Optical arrays; Optical interferometry; Optical sensors; Phase measurement; Resonance; Spatial resolution; Wavelength measurement;
Journal_Title :
Lightwave Technology, Journal of
