Title :
Optimal design of IRIS-based polarimetric intrinsic fiber optic current sensors
Author :
Fang, Xiaojun ; Claus, Richard O.
Author_Institution :
Telecommun. & Inf. Sci. Lab., Kansas Univ., Lawrence, KS, USA
fDate :
7/1/1996 12:00:00 AM
Abstract :
Performance of reciprocity-compensated polarimetric fiber optic current sensors are analyzed for typical low-birefringence fibers. The intensity-based reciprocity-insensitive structure (IRIS) can effectively balance the birefringent and lossy influences in intrinsically low-birefringence fiber-based current sensors, while supplementary techniques such as wavelength control and pole-zero cancellation are needed to eliminate the strong polarization coupling effect in spun fiber-based sensors. It is shown from simulation that the stability of the sensor can be maximized by using the IRIS and a suitable initial birefringence
Keywords :
birefringence; compensation; electric current measurement; fibre optic sensors; optical design techniques; optical fibre couplers; optimisation; polarimeters; polarimetry; stability; IRIS-based polarimetric intrinsic fiber optic current sensors; initial birefringence; intensity-based reciprocity-insensitive structure; intrinsically low-birefringence fiber-based current sensors; lossy influences; low-birefringence fibers; optimal design; pole-zero cancellation; reciprocity-compensated polarimetric fiber optic current sensors; simulation; spun fiber-based sensors; stability; strong polarization coupling effect; wavelength control; Birefringence; Current supplies; Iris; Optical design; Optical fiber losses; Optical fiber polarization; Optical fiber sensors; Optical fibers; Performance analysis; Stability;
Journal_Title :
Lightwave Technology, Journal of
