Title :
Phase-Preserving Power Limiting Function Using InP on SoI Photonic Crystal Nanocavity
Author :
Trung-Hien Nguyen ; Lengle, Kevin ; Bazin, Alexandre ; Bramerie, L. ; Peucheret, Christophe ; Gay, M. ; Sentieys, Olivier ; Simon, J.-C. ; Raj, Ranga ; Raineri, Fabrice
Author_Institution :
Foton Lab., Univ. Eur. de Bretagne, Rennes, France
Abstract :
We report on the use of an InP/silicon-on-insulator hybrid photonic crystal nanocavity for the realization of a phase-preserving all-optical power limiter. This function is experimentally demonstrated with 20-Gbit/s nonreturn-to-zero quadrature phase-shift-keying signals. Histogram-based measurements of the phase distributions indicate negligible variations of the phase noise, whereas the amplitude fluctuations are suppressed, confirming the effectiveness of cavity switching for implementing the power-limiter function. Significant power penalty reduction is achieved, indicating a promising application for future photonic circuits.
Keywords :
III-V semiconductors; indium compounds; integrated optics; integrated optoelectronics; nanophotonics; optical information processing; optical limiters; optical switches; phase shift keying; photonic crystals; silicon-on-insulator; wide band gap semiconductors; InP-Si; amplitude fluctuations; bit rate 20 Gbit/s; cavity switching; histogram-based measurements; hybrid photonic crystal nanocavity; nonreturn-to-zero quadrature phase-shift-keying signals; phase noise; phase-preserving all-optical power limiter; phase-preserving power limiting function; photonic circuits; power penalty reduction; silicon-on-insulator; Bit error rate; Cavity resonators; Noise; Noise level; Optical fibers; Phase shift keying; Optical signal processing; Photonic integrated circuits; photonic crystal nanocavity; power-limiter;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2014.2319248
