DocumentCode
1551139
Title
The statistics of PMD-induced chromatic fiber dispersion
Author
Foschini, Gerard J. ; Jopson, R.M. ; Nelson, Lynn E. ; Kogelnik, Herwig
Author_Institution
Bell Labs., Lucent Technol., Holmdel, NJ, USA
Volume
17
Issue
9
fYear
1999
fDate
9/1/1999 12:00:00 AM
Firstpage
1560
Lastpage
1565
Abstract
This paper presents a statistical description of polarization dependent chromatic dispersion (PCD) in optical fibers due to second-order polarization mode dispersion (PMD). This chromatic dispersion is the cause of pulse broadening and compression of the signal components propagating in the principal states of polarization. We show here that, remarkably, the probability density function of PCD has the form of the energy density of a first-order optical soliton. We report measurements that are in agreement with the prediction of this soliton density. Moreover, since a large number of independent experimental samples are difficult to obtain, we also report simulations of the experimental process and these serve to underscore the agreement between theory and measurement. The probability density functions of first and second-order PMD vectors are spherically symmetric. However, these vectors are not statistically independent. The mean square depolarization with respect to wavelength of a launched pulse is revealed to be 33% stronger than expected for spherical symmetry in the absence of dependence, while the mean square PCD is weaker by 67%
Keywords
optical fibre communication; optical fibre dispersion; optical fibre polarisation; optical fibre theory; optical solitons; probability; PMD-induced chromatic fiber dispersion statistics; chromatic dispersion; first-order optical soliton; optical fibers; polarization dependent chromatic dispersion; principal states of polarization; probability density function; probability density functions; second-order PMD vectors; second-order polarization mode dispersion; soliton density; statistical description; Chromatic dispersion; Optical fiber dispersion; Optical fiber polarization; Optical fibers; Optical propagation; Optical pulses; Polarization mode dispersion; Probability density function; Pulse compression methods; Statistics;
fLanguage
English
Journal_Title
Lightwave Technology, Journal of
Publisher
ieee
ISSN
0733-8724
Type
jour
DOI
10.1109/50.788561
Filename
788561
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