Fysikbaserad djupinlärning för optisk dataöverföring och distribuerad avkänning
Forskningsprojekt, 2021 – 2024

In order to cope with ever-increasing data traffic demands, recent years have witnessed an explosion of research interest in replacing handcrafted communication algorithms with machine-learning-based artificial intelligence (AI). However, prior work has largely resorted to massively overparameterized neural networks, resulting in unrealistic hardware requirements and unsatisfactory black-box solutions. This project will instead explore a new approach, specifically for optical fiber systems, that will not only lead to improved transmission performance, but also transform already-deployed communication fibers into intelligent sensors providing real-time information about various physical effects along the propagation path, e.g., mechanical stresses or vibrations. Our approach leverages well-established physical models and principles as a foundation, in particular the nonlinear differential equations governing the propagation dynamics. The proposed 4-year project is divided into four objectives/tasks: (i) receiver-side machine-learning models, (ii) transmitter-side signal shapers, (iii) data-driven optimization, and (iv) trade-offs between communication and sensing. The data used for training the developed solutions will originate from simulations supplemented by lab transmission experiments. Our target is to develop new AI-based solutions that combine, for the first time, high-speed optical data transmission and distributed sensing capabilities into a single DSP platform.

Deltagare

Christian Häger (kontakt)

Chalmers, Elektroteknik, Kommunikation, Antenner och Optiska Nätverk

Andra projekt Forskning

Finansiering

Vetenskapsrådet (VR)

Projekt-id: 2020-04718
Finansierar Chalmers deltagande under 2021–2024

Andra projekt

Publikationer

2023

Mer information

Senast uppdaterat

2021-11-03

Fysikbaserad djupinlärning för optisk dataöverföring och distribuerad avkänning
Forskningsprojekt, 2021 – 2024

Deltagare

Christian Häger (kontakt)

Finansiering

Vetenskapsrådet (VR)

Publikationer

Spatial Signal Design for Positioning via End-to-End Learning

Semi-Supervised End-to-End Learning for Integrated Sensing and Communications

End-to-End Learning for VCSEL-based Optical Interconnects: State-of-the-Art, Challenges, and Opportunities

FPGA Implementation of Multi-Layer Machine Learning Equalizer with On-Chip Training

Model-Driven End-to-End Learning for Integrated Sensing and Communication

Model-based end-to-end learning for multi-target integrated sensing and communication

Blind Frequency-Domain Equalization Using Vector-Quantized Variational Autoencoders

Improved Polarization Tracking in the Presence of PDL

FPGA-based Optical Kerr Effect Emulator

Data-Driven Estimation of Capacity Upper Bounds

Learning Optimal PAM Levels for VCSEL-based Optical Interconnects

Polarization Tracking in the Presence of PDL and Fast Temporal Drift

Mer information

Senast uppdaterat

Fysikbaserad djupinlärning för optisk dataöverföring och distribuerad avkänning Forskningsprojekt, 2021 – 2024

Deltagare

Christian Häger (kontakt)

Finansiering

Vetenskapsrådet (VR)

Publikationer

Mer information

Senast uppdaterat

Fysikbaserad djupinlärning för optisk dataöverföring och distribuerad avkänning
Forskningsprojekt, 2021 – 2024