DocumentCode
73857
Title
Frequency-Derivative Measurement Technique for Dispersive Effects in Single-Mode Fiber Systems
Author
Askarov, Daulet ; Szafraniec, Bogdan ; Baney, Douglas M. ; Kahn, Joseph M.
Author_Institution
Dept. of Electr. Eng., Stanford Univ., Stanford, CA, USA
Volume
32
Issue
22
fYear
2014
fDate
Nov.15, 15 2014
Firstpage
4456
Lastpage
4463
Abstract
An optical dispersion analysis and measurement technique based on frequency derivatives of the Jones matrix is presented. This approach enables measurement of all scalar and polarization-dependent phase and amplitude dispersion effects over a broad wavelength range in a single sweep. Owing to its differential nature, it can be more accurate than techniques that calculate dispersion by comparing phase and amplitude measurements from adjacent wavelengths in a sweep. The method involves measuring eight elementary parameters related to the frequency derivative of the Jones matrix. An experimental setup and data analysis methods for measuring the elementary parameters are presented. Three optical devices exhibiting various dispersive effects are tested, and the ability to measure all the elementary parameters is demonstrated. Elementary parameter estimation error is 1-2 ps in this proof-of-concept experiment.
Keywords
optical fibre dispersion; optical fibre polarisation; optical variables measurement; parameter estimation; phase measurement; Jones matrix; amplitude dispersion effects; amplitude measurements; dispersive effects; elementary parameter estimation error; frequency derivatives; frequency-derivative measurement technique; optical dispersion analysis; phase measurements; polarization-dependent phase dispersion effects; single-mode fiber systems; Dispersion; Frequency measurement; Frequency modulation; Optical fibers; Optical polarization; Wavelength measurement; Optical fiber devices; optical fiber dispersion; optical variables measurement;
fLanguage
English
Journal_Title
Lightwave Technology, Journal of
Publisher
ieee
ISSN
0733-8724
Type
jour
DOI
10.1109/JLT.2014.2358585
Filename
6901188
Link To Document