Biased π-Shifted Low-Coherence Interferometry for Measuring Polarization Mode Dispersion (PMD)

Conventional low-coherence interferometry LCI has been employed in Ž . the measurement of polarization mode dispersion PMD of fiber-optic components and fibers. However, the smallest PMD, which can be measured using this technique, is limited by the coherence length of the source. We propose and study a biased -shifted Michelson interferometer where a Ž . birefringent crystal biasing crystal is inserted in front of the interferometer to introduce a bias differential group delay larger than the coherence time of the source. In this way, the limitation imposed by the source coherence time is overcome and PMDs much smaller than the source coherence time, in the order of several femtoseconds, can be measured. A theoretical model of the biased -shifted LCI is developed based on Jones calculus. Experimental observations have been demonstrated to agree well with the theoretical model. Measurements for the PMD have been shown and compared with those obtained through the Jones matrix eigenanalysis.