Optimized spinning design for low PMD fibers: an analytical approach

“…As was already observed for polarization-maintaining spun fibers [9], this result implies that if is known, it is much more effective to choose the spin rate properly, rather than spinning as fast as possible.…”

“…It may be proved that these amplitudes correspond to those spins that make the DGD of a deterministic fiber a periodic function [18]. This result explains the numerical observation [9] that spin functions optimized for a polarization-maintaining fiber allow quasioptimal DGD reduction, even when the fiber birefringence evolves randomly. For example, we may calculate the mean DGD of a polarization-maintaining fiber spun according to the function…”

“…While it has been found empirically that it is more effective to spin fibers at a rate that changes periodically as they are drawn [6]- [8], rather than spinning them at a constant rate, the reasons for the advantage of periodic over constant spinning have not been clear. A great part of the analysis to date has treated spun fibers with a constant birefringence and no random variations [5]- [9]. This case is a useful starting point for the study of spun fibers because the analysis is simple; however, it does not correspond to the usual case in telecommunication fibers.…”

“…If that fiber is spun according to a periodic function of period , it may be shown (see Section IV) that in the long-length regime, the mean DGD of the spun fiber equals (9) In (9), is the mean DGD that the same fiber would have if it were not spun, and and are defined as (10) where and . We remark that the expressions given in (10) depend only on the ratio .…”

An analytical formula for the mean differential group delay of randomly birefringent spun fibers

“…As was already observed for polarization-maintaining spun fibers [9], this result implies that if is known, it is much more effective to choose the spin rate properly, rather than spinning as fast as possible.…”

“…It may be proved that these amplitudes correspond to those spins that make the DGD of a deterministic fiber a periodic function [18]. This result explains the numerical observation [9] that spin functions optimized for a polarization-maintaining fiber allow quasioptimal DGD reduction, even when the fiber birefringence evolves randomly. For example, we may calculate the mean DGD of a polarization-maintaining fiber spun according to the function…”

“…While it has been found empirically that it is more effective to spin fibers at a rate that changes periodically as they are drawn [6]- [8], rather than spinning them at a constant rate, the reasons for the advantage of periodic over constant spinning have not been clear. A great part of the analysis to date has treated spun fibers with a constant birefringence and no random variations [5]- [9]. This case is a useful starting point for the study of spun fibers because the analysis is simple; however, it does not correspond to the usual case in telecommunication fibers.…”

“…If that fiber is spun according to a periodic function of period , it may be shown (see Section IV) that in the long-length regime, the mean DGD of the spun fiber equals (9) In (9), is the mean DGD that the same fiber would have if it were not spun, and and are defined as (10) where and . We remark that the expressions given in (10) depend only on the ratio .…”

An analytical formula for the mean differential group delay of randomly birefringent spun fibers

“…Two approaches have been suggested to model the reduction of the PMD in the spun fibres, one of which is based on the evolution of the polarization state (Galtarossa et al, 2001;Ming-Jun &Nolan, 1998). The evolution of the vector representing the polarization dispersion is ruled by the dynamic equation which is linked to the vector of the local birefringence.…”

Spun Fibres for Compensation of PMD: Theory and Characterization

Low-PMD spun fibers