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A Unified Implementation of Several Baseline Deep Learning Models for Automatic Modulation Recognition

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Deep Learning Based Automatic Modulation Recognition: Models, Datasets, and Challenges

Source code for the paper "Deep Learning Based Automatic Modulation Recognition: Models, Datasets, and Challenges", which is published in Digital Signal Processing.

Representative and up-to-date models in the AMR field are implemented on four different datasets (RML2016.10a, RML2016.10b, RML2018.01a, HisarMod2019.1), providing a unified reference for interested researchers.

The article is available here:Deep Learning Based Automatic Modulation Recognition: Models, Datasets, and Challenges

If you have any question, please contact e-mail: [email protected]

Abstract

Automatic modulation recognition (AMR) detects the modulation scheme of the received signals for further signal processing without needing prior information, and provides the essential function when such information is missing. Recent breakthroughs in deep learning (DL) have laid the foundation for developing high-performance DL-AMR approaches for communications systems. Comparing with traditional modulation detection methods, DL-AMR approaches have achieved promising performance including high recognition accuracy and low false alarms due to the strong feature extraction and classification abilities of deep neural networks. Despite the promising potential, DL-AMR approaches also bring concerns to complexity and explainability, which affect the practical deployment in wireless communications systems. This paper aims to present a review of the current DL-AMR research, with a focus on appropriate DL models and benchmark datasets. We further provide comprehensive experiments to compare the state of the art models for single-input-single-output (SISO) systems from both accuracy and complexity perspectives, and propose to apply DL-AMR in the new multiple-input-multiple-output (MIMO) scenario with precoding. Finally, existing challenges and possible future research directions are discussed.

Content

Experimental comparison for SISO system

Accuracy

Recognition accuracy comparison of the state-of-the-art models on (a) RML2016.10a, (b) RML2016.10b, (c) RML2018.01a, (d) HisarMod2019.1 Fig.1 Recognition accuracy comparison of the state-of-the-art models on (a) RML2016.10a, (b) RML2016.10b, (c) RML2018.01a, (d) HisarMod2019.1.

Parameter Comparison

Table1 Model size and complexity comparison on the four datasets (A: RML2016.10a, B: RML2016.10b, C: RML2018.01a, D: HisarMod2019.1). 1667809469605

Confusion matrix

combine_revise2022512_r Fig.2 Confusion matrices. A, B and C represent the confusion matrices obtained on the RML2016.10a, RML2016.10b, and RML2018.01a, respectively. The numerical indexes 1 - 14 denote CNN1, CNN2, MCNET, IC-AMCNET, ResNet, DenseNet, GRU, LSTM, DAE, MCLDNN, CLDNN, CLDNN2, CGDNet, PET-CGDNN.

Dataset

Table2 Main AMR open datasets for SISO systems. 1658233963147

Dataset Link Notes
RML2016.10a, RML2016.10b, RML2018.01a RML If RML2018 dataset is too large, you can use SubsampleRML2018.py to sample the dataset to get a partial dataset for experimentation.
HisarMod2019.1 HisarMod In our experiments, the dataset was converted from a .CSV file to a .MAT file, which can be found in Link.

Related Papers

Model Paper name Publication year
CNN1 Convolutional Radio Modulation Recognition Networks 2016
CNN2 Robust and Fast Automatic Modulation Classification with CNN under Multipath Fading Channels 2020
MCNET MCNet: An Efficient CNN Architecture for Robust Automatic Modulation Classification 2020
IC-AMCNET CNN-Based Automatic Modulation Classification for Beyond 5G Communications 2020
ResNet Deep neural network architectures for modulation classification 2017
DenseNet Deep neural network architectures for modulation classification 2017
GRU Automatic Modulation Classification using Recurrent Neural Networks 2017
LSTM Deep Learning Models for Wireless Signal Classification With Distributed Low-Cost Spectrum Sensors 2018
DAE Real-Time Radio Technology and Modulation Classification via an LSTM Auto-Encoder 2022
MCLDNN A Spatiotemporal Multi-Channel Learning Framework for Automatic Modulation Recognition 2020
CLDNN Deep Architectures for Modulation Recognition 2017
CLDNN2 Deep neural network architectures for modulation classification 2017
CGDNet CGDNet: Efficient Hybrid Deep Learning Model for Robust Automatic Modulation Recognition 2021
PET-CGDNN An Efficient Deep Learning Model for Automatic Modulation Recognition Based on Parameter Estimation and Transformation 2021
1DCNN-PF Automatic Modulation Classification Using Parallel Fusion of Convolutional Neural Networks 2019

Environment

These models are implemented in Keras, and the environment setting is:

  • Python 3.6.10
  • TensorFlow-gpu 1.14.0
  • Keras-gpu 2.2.4

Remarks

You will need to download the appropriate dataset and change the flie path to the corresponding dataset in your code. There is no guarantee that the code can run sucessfully under other environmental configurations, but there may be performance differences due to different hardware conditions.

About DAE: In the author's open source code, decoder uses the TimeDistributed layer. In our initial implementation, decoder unfolds the data and uses a fully connected layer to reconstruct the input, so the difference is described here. (Source code for DAE) We updated the DAE source code and experimental results with TimeDistributed layer as decoder in our website.

Acknowledgement

Our code is partly based on leena201818. Thanks leena201818 and wzjialang for their great work!

Citation

Please cite the literature we refer to if they are helpful to your work. If our work is helpful to your research, please cite:

@article{ZHANG2022103650,
    title={Deep Learning Based Automatic Modulation Recognition: Models, Datasets, and Challenges},
    author={Fuxin Zhang and Chunbo Luo and Jialang Xu and Yang Luo and FuChun Zheng},
    journal={Digital Signal Processing},
    year={2022},
    doi = {https://doi.org/10.1016/j.dsp.2022.103650}
}

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