Litcius/Paper detail

Generative machine learning for robust free-space communication

Sanjaya Lohani, Erin M. Knutson, Ryan T. Glasser

2020Communications Physics44 citationsDOIOpen Access PDF

Abstract

Abstract Free-space optical communications systems suffer from turbulent propagation of light through the atmosphere, attenuation, and receiver detector noise. These effects degrade the quality of the received state, increase cross-talk, and decrease symbol classification accuracy. We develop a state-of-the-art generative neural network (GNN) and convolutional neural network (CNN) system in combination, and demonstrate its efficacy in simulated and experimental communications settings. Experimentally, the GNN system corrects for distortion and reduces detector noise, resulting in nearly identical-to-desired mode profiles at the receiver, requiring no feedback or adaptive optics. Classification accuracy is significantly improved when these generated modes are demodulated using a CNN that is pre-trained with undistorted modes. Using the GNN and CNN system exclusively pre-trained with simulated optical profiles, we show a reduction in cross-talk between experimentally-detected noisy/distorted modes at the receiver. This scalable scheme may provide a concrete and effective demodulation technique for establishing long-range classical and quantum communication links.

Topics & Concepts

Computer scienceDemodulationConvolutional neural networkDetectorArtificial intelligenceCommunications systemScalabilityScheme (mathematics)Artificial neural networkOptical communicationReduction (mathematics)Machine learningSymbol (formal)Pattern recognition (psychology)Generative grammarMode (computer interface)Distortion (music)Electronic engineeringQuality (philosophy)Speech recognitionTransmitterDimensionality reductionOptical Wireless Communication TechnologiesNeural Networks and Reservoir ComputingOrbital Angular Momentum in Optics