Title :
Nonlocal Nonlinear Electro-Optic Phase Dynamics Demonstrating 10 Gb/s Chaos Communications
Author :
Lavrov, Roman ; Jacquot, Maxime ; Larger, Laurent
Author_Institution :
Opt. Dept., Univ. of Franche-Comte, Besançon, France
Abstract :
We report on successful 10 Gb/s transmission of a message hidden in a chaotic optical phase over more than 100 km of an installed fiber optic network. This represents the best performance to date for so-called optical chaos communication, a physical layer oriented optical data encryption technique. Such performances was achieved through the use of a recently developed electro-optic nonlinear delay phase dynamics, inspired from differential phase modulation techniques. The setup appears as a superior alternative to the most popular architectures, i.e., the ones involving laser rate equations subjected to delayed feedback. It is compatible with standard dispersion compensation techniques and optical amplification, as shown by two field experiments over installed fiber optic networks.
Keywords :
chaotic communication; cryptography; optical fibre networks; bit rate 10 Gbit/s; chaos communications; chaotic optical phase; differential phase modulation techniques; electro-optic nonlinear delay phase dynamics; fiber optic networks; message transmission; nonlocal nonlinear electro-optic phase dynamics; optical amplification; optical chaos communication; physical layer oriented optical data encryption technique; standard dispersion compensation techniques; Adaptive optics; Chaotic communication; Nonlinear optics; Optical feedback; Phase modulation; Receivers; Chaos synchronization; electro-optic (EO) feedback; nonlinear delay dynamics; optical chaos communications; optical phase modulation;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2010.2049987
