Title :
Theoretical analysis and numerical simulation of inter-modal four-wave-mixing in few mode fibers
Author :
Yi Weng ; Xuan He ; Zhongqi Pan ; Bo Zhu ; Junyi Wang
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of Louisiana at Lafayette, Lafayette, LA, USA
Abstract :
Analogous to single-mode fiber, nonlinear effects may eventually limit the information capacity in next generation long-haul few-mode fiber (FMF) transmission systems. In this paper, we theoretically and numerically investigate inter-modal four-wave mixing (IM-FWM) among up to four spatial modes in FMFs. Different forms of multi-mode non-linear Schrödinger equation (MM-NLSE) for two, three and four spatial modes are derived, along with up to six types of wave/mode distributions and their corresponding phase matching conditions. We analyze the mixed effects of differential mode group delay (DMGD), chromatic dispersion (CD), random mode coupling (RMC) and wavelength separation upon IM-FWM efficiency in FMF.
Keywords :
Schrodinger equation; channel capacity; multiwave mixing; optical fibre communication; optical fibre dispersion; optical phase matching; CD; DMGD; FMF transmission systems; IM-FWM efficiency; MM-NLSE; RMC; chromatic dispersion; differential mode group delay; few mode fibers; few-mode fiber transmission systems; information capacity; intermodal four-wave-mixing; multimode nonlinear Schrodinger equation; numerical simulation; phase matching conditions; random mode coupling; single-mode fiber; spatial modes; theoretical analysis; wave-mode distributions; wavelength separation; Couplings; Equations; Frequency conversion; Mathematical model; Optical fiber dispersion; Optical fiber networks; Optical fibers; Nonlinear optics; few-mode fibers (FMF); inter-modal four-wave mixing (IM-FWM); multimode nonlinear Schrödinger equation (MM-NLSE); phase-matching condition;
Conference_Titel :
Wireless and Optical Communication Conference (WOCC), 2014 23rd
Conference_Location :
Newark, NJ
DOI :
10.1109/WOCC.2014.6839935
