YAHYA-6G | Dynamic resource Scheduling in Massive MIMO based NOMA with RF imperfections and Energy Harvesting for 6G networks

Summary
YAHYA-6G aims to propose new signal processing solutions doped with machine-learning. We will focus on the detection
and compensation of RF imperfections in mMIMO (massive Multiple input Multiple output) based NOMA (Non-orthogonal multiple
access) pair . In other hand, YAHYA-6G target is to minimize the long-term power consumption based on the stochastic optimization theory for mMIMO-NOMA IoT networks with EH (Energy Harvesting) in presence of RF imperfections. Thus the objectives of the YAHYA-6G project are:
1- Identify major RF imperfections that may occur in a multi-access / multi-antenna broadband system.
2- Propose new solutions to optimize the energy efficiency at the RF transmitters. This solution will focus on the power amplifier that represents 60 at 70% of the energy consumed in an RF transmitter.
3- Analyze the impact of these RF imperfections on mobile radio systems exploiting NOMA technologies.
4- Propose a Deep Learning online learning process to detect the NOMA channel characteristics and compensate the effect of HPA nonlinearity. A joint detection of the NOMA interference and HPA (High Power Amplifier) nonlinearity will be studied
in mMIMO-NOMA system.
5- Resolve a non convex based problem coping with the expected 6G requirements, with a particular focus on optimal resource scheduling and computation capacity allocation and reducing energy consumption of wireless devices, through a set of new algorithms .
6- Realize a demonstrator based on the SDR (Software Defined Radio) USRP cards on which some algorithms developed in
the project will be implemented.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/101130808
Start date: 01-01-2024
End date: 31-12-2025
Total budget - Public funding: - 172 618,00 Euro
Cordis data

Original description

YAHYA-6G aims to propose new signal processing solutions doped with machine-learning. We will focus on the detection
and compensation of RF imperfections in mMIMO (massive Multiple input Multiple output) based NOMA (Non-orthogonal multiple
access) pair . In other hand, YAHYA-6G target is to minimize the long-term power consumption based on the stochastic optimization theory for mMIMO-NOMA IoT networks with EH (Energy Harvesting) in presence of RF imperfections. Thus the objectives of the YAHYA-6G project are:
1- Identify major RF imperfections that may occur in a multi-access / multi-antenna broadband system.
2- Propose new solutions to optimize the energy efficiency at the RF transmitters. This solution will focus on the power amplifier that represents 60 at 70% of the energy consumed in an RF transmitter.
3- Analyze the impact of these RF imperfections on mobile radio systems exploiting NOMA technologies.
4- Propose a Deep Learning online learning process to detect the NOMA channel characteristics and compensate the effect of HPA nonlinearity. A joint detection of the NOMA interference and HPA (High Power Amplifier) nonlinearity will be studied
in mMIMO-NOMA system.
5- Resolve a non convex based problem coping with the expected 6G requirements, with a particular focus on optimal resource scheduling and computation capacity allocation and reducing energy consumption of wireless devices, through a set of new algorithms .
6- Realize a demonstrator based on the SDR (Software Defined Radio) USRP cards on which some algorithms developed in
the project will be implemented.

Status

TERMINATED

Call topic

HORIZON-WIDERA-2022-TALENTS-04-01

Update Date

31-10-2023
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Horizon Europe
HORIZON.4 Widening Participation and Strengthening the European Research Area
HORIZON.4.1 Widening participation and spreading excellence
HORIZON.4.1.5 Fostering brain circulation of researchers and excellence initiatives
HORIZON-WIDERA-2022-TALENTS-04
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