Title :
Parallelizable, Bidirectional Method for Simulating Optical-Signal Propagation
Author :
Hollenbeck, Dawn ; Cantrell, Cyrus D.
Author_Institution :
Dept. of Phys., Rochester Inst. of Technol., Rochester, NY, USA
fDate :
6/15/2009 12:00:00 AM
Abstract :
We have developed and tested a parallelizable, bidirectional (PB) numerical algorithm for the simulation of propagating laser pulse trains and oppositely propagating laser beams or pulse trains. The PB approach replaces iterative simulation of counterpropagating Raman amplification, stimulated Brillouin scattering, reflections and Rayleigh scattering. Initial tests have shown that at least 98% of the computational core of a finite-difference time-domain test program that uses the new PB algorithm is parallelizable, implying a factor of 7 speed-up with eight processors (for example). This result is important for the design of optical transmission systems because the PB approach increases size of a system that can be designed and simulated in a given time.
Keywords :
finite difference time-domain analysis; laser beams; optical design techniques; optical fibre communication; optical transmitters; Rayleigh scattering; bidirectional method; counterpropagating Raman amplification; finite-difference time-domain test program; laser beams; laser pulse train propagation; optical fiber communication; optical networks; optical transmission system design; optical-signal propagation; parallelizable numerical algorithm; stimulated Brillouin scattering; Finite difference methods; Raman scattering; nonlinear optics; optical fiber amplifiers; optical fiber communication; optical fiber dispersion; optical fibers; optical propagation; parallel processing;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2008.2009471
