Title :
Nonlinear pulse propagation in long-period fiber gratings: theory and experiment
Author :
Kutz, J. Nathan ; Eggleton, Benjamin J. ; Stark, Jason B. ; Slusher, Richart E.
Author_Institution :
Program in Appl. & Comput. Math., Princeton Univ., NJ, USA
fDate :
10/1/1997 12:00:00 AM
Abstract :
In this paper, we discuss theoretical and experimental aspects of nonlinear pulse propagation in long-period fiber gratings. We derive nonlinear coupled mode equations for co-propagating core and cladding modes in a long-period fiber grating and show that the intensity dependent index can be used to tune the mode coupling, thereby creating a mechanism for pulseshaping and all-optical switching. Extensive numerical simulations, which describe the nonlinear pulse dynamics, are compared with experiments. We discuss the application of these nonlinear effects to signal processing in all-optical fiber communications
Keywords :
diffraction gratings; high-speed optical techniques; nonlinear optics; optical fibre cladding; optical fibre communication; optical fibre theory; optical fibres; optical information processing; optical switches; refractive index; all-optical fiber communications; all-optical switching; co-propagating cladding modes; co-propagating core modes; intensity dependent index; long-period fiber gratings; mode coupling tuning; nonlinear coupled mode equations; nonlinear effects; nonlinear pulse dynamics; nonlinear pulse propagation; numerical simulations; pulseshaping; signal processing; Bragg gratings; Couplings; Fiber gratings; Optical fiber devices; Optical fiber polarization; Optical fiber theory; Optical signal processing; Periodic structures; Resonance; Solitons;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/2944.658602
