Using coupled-mode theory, we develop a theoretical model to analyze the effects of fiber spin profiles on polarization mode dispersion (PMD). Constant, sinusoidal, and frequency-modulated spin profiles are examined, and phase-matching conditions are analyzed. Our analysis shows that PMD can be reduced effectively by use of frequency-modulated spin profiles.
A two-fiber optical channel shared protection ring including node architecture, signaling protocol, control hardware, and software is designed and implemented experimentally. For a ring with four nodes and two wavelengths, a total protection switching time of 6.8 ms is demonstrated along with a revert-to-working switching time of 1.6 ms. Experimental results show that the switching time scales linearly with number of nodes and number of wavelengths. The system can protect a ring with 16 nodes, 1200 km circumference, and 40 wavelengths in less than 50 ms.
Using the coupled-mode theory, we have developed a theoretical model to analyze the effects of lateral load and external twist on polarization-mode dispersion (PMD) of spun and unspun fibers. Modeling results show that spun and unspun fibers have very different PMD responses to lateral load and external twist. Experimental results show good agreement with the theory.
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