Title :
Spatial resolution enhancement of a Brillouin-distributed sensor using a novel signal processing method
Author :
Brown, Anthony W. ; DeMerchant, Michael D. ; Bao, Xiaoyi ; Bremner, Theodore W.
Author_Institution :
Dept. of Phys., New Brunswick Univ., Fredericton, NB, Canada
fDate :
7/1/1999 12:00:00 AM
Abstract :
It is known that the ultimate spatial resolution for a Brillouin-based sensor is limited by the lifetime of the phonons in the fiber that mediate the Brillouin loss process. At optical pulse widths less than 10 ns (corresponding to one meter spatial resolution) the Brillouin line width is considerably broadened, causing a severe penalty in resolving the Brillouin frequency shift. Around 5 ns the Brillouin line width is too broad to allow an accurate frequency determination. The fiber optics group at the University of New Brunswick, Canada, has recently developed an automated system for strain measurements in a distributed sensing system that uses a novel signal processing technique to measure strain at resolutions finer than the Brillouin line width limit. Strain has been resolved to 20 με at 500 mm and to 40 με at 250 mm
Keywords :
Brillouin spectra; distributed sensors; fibre optic sensors; optical fibre losses; optical information processing; strain sensors; 5 ns; Brillouin frequency shift; Brillouin line width; Brillouin line width broadening; Brillouin line width limit; Brillouin loss process; Brillouin-based sensor; Brillouin-distributed sensor; accurate frequency determination; distributed sensing system; fibre optic sensors; optical pulse widths; severe penalty; signal processing method; spatial resolution; spatial resolution enhancement; strain measurements; ultimate spatial resolution; Frequency; Optical fiber losses; Optical fiber sensors; Optical fibers; Optical pulses; Optical signal processing; Phonons; Signal resolution; Spatial resolution; Strain measurement;
Journal_Title :
Lightwave Technology, Journal of
