Synchronization phenomena of two chaotically emitting semiconductor lasers subject to delayed optical feedback are investigated. The lasers are unidirectionally coupled via their optical fields. Our experimental and numerical studies demonstrate that the relative optical feedback phase is of decisive importance: a characteristic synchronization scenario evolves under variation of the relative optical-feedback phase mediating cyclically between chaos synchronization in conjunction with coherent fields, and uncorrelated states in conjunction with incoherent fields. As a key result, we propose, and numerically demonstrate, a novel ON/OFF phase shift keying method opening up new perspectives for applications in communication systems using chaotic carriers.
%0 Journal Article
%1 HEI02a
%A Heil, T.
%A Mulet, J.
%A Fischer, I.
%A Mirasso, C. R.
%A Peil, M.
%A Colet, P.
%A Elsäßer, W.
%D 2002
%J Quantum Electronics, IEEE Journal of
%K carriers, chaos chaos, chaos-encrypted chaotic chaotically characteristic coherent communication communication, coupled delayed emitting equipment, external-cavity feedback feedback, fields, incoherent keying, laser lasers, optical optical-feedback phase phase, phenomena, relative scenario, semiconductor shift states, synchronisationON/OFF synchronization synchronization, systems, uncorrelated unidirectionally
%N 9
%P 1162--1170
%R 10.1109/jqe.2002.801950
%T ON/OFF phase shift keying for chaos-encrypted communication using external-cavity semiconductor lasers
%V 38
%X Synchronization phenomena of two chaotically emitting semiconductor lasers subject to delayed optical feedback are investigated. The lasers are unidirectionally coupled via their optical fields. Our experimental and numerical studies demonstrate that the relative optical feedback phase is of decisive importance: a characteristic synchronization scenario evolves under variation of the relative optical-feedback phase mediating cyclically between chaos synchronization in conjunction with coherent fields, and uncorrelated states in conjunction with incoherent fields. As a key result, we propose, and numerically demonstrate, a novel ON/OFF phase shift keying method opening up new perspectives for applications in communication systems using chaotic carriers.
@article{HEI02a,
abstract = {Synchronization phenomena of two chaotically emitting semiconductor lasers subject to delayed optical feedback are investigated. The lasers are unidirectionally coupled via their optical fields. Our experimental and numerical studies demonstrate that the relative optical feedback phase is of decisive importance: a characteristic synchronization scenario evolves under variation of the relative optical-feedback phase mediating cyclically between chaos synchronization in conjunction with coherent fields, and uncorrelated states in conjunction with incoherent fields. As a key result, we propose, and numerically demonstrate, a novel ON/OFF phase shift keying method opening up new perspectives for applications in communication systems using chaotic carriers.},
added-at = {2009-03-03T17:19:04.000+0100},
author = {Heil, T. and Mulet, J. and Fischer, I. and Mirasso, C. R. and Peil, M. and Colet, P. and Els{\"a}{\ss}er, W.},
biburl = {https://www.bibsonomy.org/bibtex/2451da2b1bb52b37dc7d3bb80c85ce2a7/bronckobuster},
doi = {10.1109/jqe.2002.801950},
interhash = {21263eedd128de4ea51186f3e3425cee},
intrahash = {451da2b1bb52b37dc7d3bb80c85ce2a7},
issn = {0018-9197},
journal = {Quantum Electronics, IEEE Journal of},
keywords = {carriers, chaos chaos, chaos-encrypted chaotic chaotically characteristic coherent communication communication, coupled delayed emitting equipment, external-cavity feedback feedback, fields, incoherent keying, laser lasers, optical optical-feedback phase phase, phenomena, relative scenario, semiconductor shift states, synchronisationON/OFF synchronization synchronization, systems, uncorrelated unidirectionally},
month = {September},
number = 9,
pages = {1162--1170},
timestamp = {2009-03-03T17:20:15.000+0100},
title = {ON/OFF phase shift keying for chaos-encrypted communication using external-cavity semiconductor lasers},
volume = 38,
year = 2002
}