Polarization dynamics of random 3D light fields

Research output: Chapter in Book/Report/Conference proceedingConference contributionScientificpeer-review

Researchers

Research units

  • University of Eastern Finland
  • Royal Institute of Technology

Abstract

We study the time evolution of the instantaneous polarization state, i.e., the polarization dynamics of random, statistically stationary three-dimensional electromagnetic fields. Two intensity-normalized polarization correlation functions which characterize the similarity of the polarization state at two times are presented. One of them is based on the generalized instantaneous Poincaré vectors and the other on the Jones vectors. We discuss the basic properties of the correlation functions and define a polarization time as a time interval over which the state of polarization does not significantly change. If the field obeys Gaussian statistics the polarization correlation functions are expressible in terms of certain second-order, measurable parameters characterizing the partial polarization and partial coherence of the field. We exemplify the formalism with a uniformly partially polarized, temporally Gaussian correlated field, and with the field at the intersection of three orthogonally propagating, linearly polarized and mutually correlated beams. The results are expected to find use in applications where the polarization fluctuations of a three-dimensional field play an important role.

Details

Original languageEnglish
Title of host publication2010 9th Euro-American Workshop on Information Optics, WIO 2010
Publication statusPublished - 2010
MoE publication typeA4 Article in a conference publication
EventEuro-American Workshop on Information Optics - Helsinki, Finland
Duration: 12 Jul 201016 Jul 2010
Conference number: 9

Publication series

NameEuro-American Workshop on Information Optics
ISSN (Print)2164-8603

Workshop

WorkshopEuro-American Workshop on Information Optics
Abbreviated titleWIO
CountryFinland
CityHelsinki
Period12/07/201016/07/2010

ID: 14966073