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Real-Time Inference of 5G NR Multi-user MIMO Neural Receivers

The code in this repository allows to design, train, and evaluate neural receivers using the NVIDIA® Sionna™ link-level simulation library and TensorFlow. Further, trained receivers can be prepared for real-time inference via NVIDIA® TensorRT™.

The following features are currently supported:

  • 5G NR compliant Multi-user MIMO PUSCH receiver
  • Training pipeline using 3GPP compliant channel models
  • TensorRT / ONNX model export for real-time inference
  • Support for varying number of PRBs, users, and different MCS schemes per user
  • End-to-end learning of custom constellations for pilotless communications [3]
  • Site-specific training using ray-tracing based channel simulations from SionnaRT as done in [2]

We recommend starting with the Jumpstart NRX Tutorial notebook for a detailed introduction and overview of the project.

The basic neural receiver architecture is introduced and described in a Neural Receiver for 5G NR Multi-user MIMO [1]. The real-time experiments and the site-specific training is described in Design of a Standard-Compliant Real-Time Neural Receiver for 5G NR [2].

Demos of this receiver architecture have been shown at Mobile World Congress 2023 and Mobile World Congress 2024.

For further details regarding solutions for deployment in an actual Radio Access Network (RAN), we recommend registering for the NVIDIA 6G Developer Program.

Summary

We introduce a neural network (NN)-based multi-user multiple-input multiple-output (MU-MIMO) receiver with full 5G New Radio (5G NR) physical uplink shared channel (PUSCH) compatibility based on graph and convolutional neural network (CGNN) components. The proposed architecture can be easily re-parametrized to an arbitrary number of sub-carriers and supports a varying number of users without the need for any additional re-training. The receiver operates on an entire 5G NR slot, i.e., it processes the entire received orthogonal frequency division multiplexing (OFDM) time-frequency resource grid by jointly performing channel estimation, equalization, and demapping. We show the importance of a carefully designed training process such that the trained receiver does not overfit to a specific channel realization and remains universal for a wide range of different unseen channel conditions. A particular focus of the architecture design is put on the real-time inference capability such that the receiver can be executed within 1 ms latency on an NVIDIA A100 GPU.

Setup

Running this code requires Sionna 0.18. To run the notebooks on your machine, you also need Jupyter. We recommend Ubuntu 22.04, Python 3.10, and TensorFlow 2.15.

For TensorRT, we recommend version 9.6 and newer. For ONNX exporting, the Python package > is required (> does not work due to a known bug).

Structure of this repository

This repository is structured in the following way:

  • config contains the system configurations for different experiments
  • notebooks contains tutorials and code examples
  • scripts contains the scripts to train, evaluate and debug the NRX
  • utils contains the NRX definition and all Python utilities
  • weights contains weights of pre-trained neural receivers for different configuration files
  • results contains pre-computed BLER performance results

The following two folders will be generated locally:

  • logs contains log files of the training
  • onnx_models contains exported ONNX neural receiver models
  • data contains a ray tracing-based dataset of channel realizations for site-specific evaluation

We recommend starting with the Jumpstart NRX Tutorial notebook for a detailed introduction and overview of the project.

References

[1] S. Cammerer, F. Aït Aoudia, J. Hoydis, A. Oeldemann, A. Roessler, T. Mayer, and A. Keller, "A Neural Receiver for 5G NR Multi-user MIMO", IEEE Workshops (GC Wkshps), Dec. 2023.

[2] R. Wiesmayr, S, Cammerer, F. Aït Aoudia, J. Hoydis, J. Zakrzewski, and Alexander Keller, "Design of a Standard-Compliant Real-Time Neural Receiver for 5G NR", arxiv preprint, 2024.

[3] F. Aït Aoudia and J. Hoydis, "End-to-end Learning for OFDM: From Neural Receivers to Pilotless Communication", IEEE Trans on Wireless Commun., 2021.

License

Copyright © 2024, NVIDIA Corporation. All rights reserved.

This work is made available under the NVIDIA License.

Citation

@software{neural_rx,
    title = {Real-time 5G NR Multi-user MIMO Receivers},
    author = {Sebastian Cammerer, Reinhard Wiesmayr, Fayçal Aït Aoudia, Jakob Hoydis, Tommi Koivisto, Jakub Zakrzewski, Ruqing Xu, Pawel Morkisz, Chris Dick, and Alexander Keller},
    note = {https://github.com/NVlabs/neural-rx},
    year = 2024
}

Acknowledgement

This work has received financial support from the European Union under Grant Agreement 101096379 (CENTRIC). Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union or the European Commission (granting authority). Neither the European Union nor the granting authority can be held responsible for them.

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