Session Overview |
Optical and Quantum Communications - Bloc 1Room: International 1 |
Date: Tuesday, June 05 |
09:00 |
Multi-stage perturbation technique based nonlinear Fourier transform for fiber optic systems
Main Author: Elham Bidaki Organization: McMaster University, Canada A multistage perturbation technique to realize the nonlinear Fourier transform is proposed. This technique uses the cascade of discrete Fourier transforms and hence, the computational cost is significantly reduced. |
09:15 |
Statistical Analysis of Performance Monitoring Data Collected in an Optical Link
Main Author: Stéphanie Allogba Organization: École de technologie supérieure, Canada In this work, we propose to use statistical analysis methods to analyze the performance of a coherent optical link by using a set of experimental BER measurements. Then, by a characterization of the BER trends with environmental factors such as temperature and wind, we implement an algorithm to classify and predict this BER trends. |
09:30 |
10-100 Gbit/s Mixed-Line-Rate Experimental Demonstration
Main Author: Mounia Lourdiane Organization: Telecom SudParis, France In this paper we analyze the feasibility of mixed-line rate transmission of 10 and 100 Gbit/s links for metro and long haul optical network. We compare theoretical models, simulation and experimental results for different transmission scenarios. |
09:45 |
MMI-based Silicon Mode (De)Multiplexer for Multichannel Parallel Data Transmission
Main Author: Rubana Priti Organization: McGill University, Canada We experimentally demonstrate an on-chip MMI-based mode (de)multiplexer for simultaneously transmitting two optical data signals. A 10-12 BER (PRBS31) is achieved with 7.3 dB insertion loss while transmitting 2×10 Gb/s optical data. |
10:00 |
Planar Optical MEMS for Next-Generation Passive Optical Networks and Data Centers Micro Optical Circuit Switches to enable Energy Efficient Universal Access
Main Author: Francois Menard Organization: AEPONYX inc., Canada Combining silicon photonics with micro-electro-mechanical-systems (Planar Optical MEMS) can enable the vision for a true universal access network by leveraging micro optical circuit switches. Converging residential, business and 5G mobile backhaul traffic over a single fiber passive optical network, as made possible by NG-PON2, can be sustained by using micro optical switches to create new, cost-effective, optical transceivers, as well as reconfigurable optical backplanes for use in Data Centers. |