Title :
Accurate, automated measurement of differential group delay dispersion and principal state variation using Jones matrix eigenanalysis
Author_Institution :
Hewlett-Packard Labs., Palo Alto, CA, USA
fDate :
7/1/1993 12:00:00 AM
Abstract :
Polarization mode dispersion can be described to first order by principal states of polarization (PSPs) and a differential group delay (DGD), and to second order by wavelength variation of the PSPs and by DGD dispersion (DGDD), the wavelength derivative of DGD. The high accuracy and wavelength resolution of Jones matrix eigenanalysis allows precise measurement of DGDD and PSP variation. A fast, automated system based on a tunable laser and an accurate, real-time polarimeter is used to measure DGD, DGDD, and PSP variation by eigenanalysis of Jones matrices measured at a series of discrete wavelengths, and the system accuracy is demonstrated. Measurements at 2-nm intervals of a device whose DGDD is a known function of wavelength yield values of DGDD which differ from theory by less than 13 fs/nm.<>
Keywords :
eigenvalues and eigenfunctions; matrix algebra; measurement by laser beam; optical dispersion; optical resolving power; polarimetry; Jones matrix eigenanalysis; automated measurement; automated system; differential group delay dispersion; laser tuning; polarization node dispersion; precise measurement; principal state variation; principal states of polarization; real-time polarimeter; system accuracy; tunable laser; wavelength resolution; wavelength variation; Chromatic dispersion; High speed optical techniques; Length measurement; Optical devices; Optical fiber amplifiers; Optical fiber devices; Optical fiber polarization; Propagation delay; Time measurement; Wavelength measurement;
Journal_Title :
Photonics Technology Letters, IEEE
