Title :
Birefringence-Dispersion-Induced Frequency Domain Nonlinearity Compensation for Polarized Low-Coherence Interferometry Demodulation
Author :
Shuang Wang ; Junfeng Jiang ; Tiegen Liu ; Kun Liu ; Jinde Yin ; Junfeng Shi ; Shengliang Zou ; Mingjiang Zhang
Author_Institution :
Key Lab. of Optoelectron. Inf. Technol., Tianjin Univ., Tianjin, China
Abstract :
A high precision demodulation method in frequency domain is proposed for a polarized low-coherence interferometer with location-dependent birefringence dispersion. By minimizing the frequency nonlinearity caused by dispersion effects, the proposed method avoids the jump errors of traditional frequency domain analysis method and exactly retrieve the absolute phase at multiselected-wavenumber point simultaneously, which makes it superior in accuracy, stability, and measurement range. We carried out experiments with an optical fiber Fabry-Pérot pressure sensing system to verify the effectiveness of the proposed method. The experiment result showed that the measured error was less than 0.049 kPa and the measurement range was widened to 285 kPa, which could be wider with suited experimental equipment and is no limit in theory.
Keywords :
Fabry-Perot interferometers; birefringence; compensation; demodulation; fibre optic sensors; light interferometry; optical fibre dispersion; optical fibre polarisation; pressure sensors; birefringence-dispersion-induced frequency domain nonlinearity compensation; dispersion effects; multiselected-wavenumber point; optical fiber Fabry-Pérot pressure sensing; polarized low-coherence interferometry demodulation; traditional frequency domain analysis; Cavity resonators; Charge coupled devices; Demodulation; Discrete Fourier transforms; Dispersion; Frequency-domain analysis; Measurement uncertainty; Fabry-Perot; Fabry???Perot; Interferometry; Pressure measurement; interferometry; pressure measurement;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2015.2490083
