Your search keyword '"OPTICAL fiber communication"' showing total 2 results

1. Simulation of an inelastic dispersive phenomenon: stimulated Brillouin scattering in a single-mode fiber segment through parallelism.

Author

Sanchez-Lara, R., Trejo-Sanchez, J. A., Lopez-Martinez, J. L., and Alvarez-Chavez, J. A.

Subjects

*HIGH performance computing, *BRILLOUIN scattering, *OPTICAL communications, *DIFFERENTIAL equations, *GRAPHICS processing units, *PARALLEL computers, *COMPUTER simulation

Abstract

Stimulated Brillouin scattering (SBS) is one of the most important nonlinear phenomena because it limits the maximum transmission power in modern optical communication systems. Unfortunately, the simulation of SBS is time-consuming, since it requires estimating the solutions for a set of complex differential equations that describe this phenomenon. In this paper, a novel high-performance computing model intended to analyze the main dispersive effects present in modern fiber communication systems is proposed. A full optical characterization of the simulation results is included and compared with the efficiency and improved speed of our parallel implementation versus a previous sequential model for SBS. Also, an evaluation of the throughput of our parallel implementation using both central processing unit multi-core and graphics processing unit is presented. Results show that parallelism increases the performance of the simulation tenfold. [ABSTRACT FROM AUTHOR]

Published

2018

2. Analysis of multichannel optical soliton collisions with asymmetric energy in strongly dispersion managed transmission networks considering higher-order effects.

Author

Guillan-Lorenzo, O., Pedrosa-Rodriguez, L., Vilar-Gomez, P., and Diaz-Otero, F. J.

Subjects

*SOLITONS, *TRANSMISSION network calculations, *WAVELENGTHS, *RAMAN scattering, *DIFFERENTIAL equations

Abstract

We study the interaction properties of optical soliton pulses propagating in a two-channel wavelength-division multiplexed strongly dispersion managed communication system. We analyze the effects of third order dispersion, Raman scattering and self-steepening using an ordinary differential equations model obtained by a variational method applied to the Generalized Nonlinear Schrödinger Equation. The validity of the model is assessed against the integration of the full nonlinear partial differential equations. The variational equations are initially solved for a single pulse in order to identify the launching parameters for each pulse in the first DM cell of the system. One pulse per wavelength is then injected in the transmission link. We then systematically study the evolution of multiplexed soliton trains and analyse the transmission system in terms of residual frequency shifts and interchannel interactions as the map strength is varied, focusing on the ratio of dissimilar peak powers in a broad range of dispersion difference values, concluding that the transmission characteristics improve by using specific values of unequal energies and considering higher-order correction terms. The work presented is an extension of previous analysis where isolated intra-channel two-pulse interactions had been addressed considering pulses with dissimilar energies. [ABSTRACT FROM AUTHOR]

Published

2018