A Transformer-Based Contrastive Semi-Supervised Learning Framework for Automatic Modulation Recognition

The application of deep learning improves the processing speed and the accuracy of automatic modulation recognition (AMR). As a result, it realizes intelligent spectrum management and electronic reconnaissance. However, deep learning-aided AMR usually requires a large number of labeled samples to obtain a reliable neural network model. In practical applications, due to economic costs and privacy constraints, there is a small number of labeled samples but a large number of unlabeled samples. This paper proposes a Transformer-based contrastive semi-supervised learning framework for AMR. First, self-supervised contrastive pre-training of the Transformer-based encoder is completed using unlabeled samples, and data augmentation is realized through time warping. Then, the pre-trained encoder and a randomly initialized classifier are fine-tuned using labeled samples, and hierarchical learning rates are employed to ensure classification accuracy. Considering the problems of applying Transformer to AMR, a convolutional transformer deep neural network is proposed, which involves convolutional embedding, attention bias, and attention pooling. In experiments, the feasibility of the framework is analyzed through linear evaluation of the framework components on the RML2016.10a dataset. Also, the proposed framework is compared with existing semi-supervised methods on RML2016.10a and RML2016.10b datasets to verify its superiority and stability.

[1]  Wei Liu,et al.  Signal Modulation Classification Based on the Transformer Network , 2022, IEEE Transactions on Cognitive Communications and Networking.

[2]  Qinghai Yang,et al.  A Transformer-based CTDNN Structure for Automatic Modulation Recognition , 2021, 2021 7th International Conference on Computer and Communications (ICCC).

[3]  Swayambhoo Jain,et al.  MCformer: A Transformer Based Deep Neural Network for Automatic Modulation Classification , 2021, 2021 IEEE Global Communications Conference (GLOBECOM).

[4]  T. Abdelzaher,et al.  Self-Contrastive Learning based Semi-Supervised Radio Modulation Classification , 2021, MILCOM 2021 - 2021 IEEE Military Communications Conference (MILCOM).

[5]  Yuan Zeng,et al.  Learning of Time-Frequency Attention Mechanism for Automatic Modulation Recognition , 2021, IEEE Wireless Communications Letters.

[6]  Timothy M. Hospedales,et al.  Self-Supervised Representation Learning: Introduction, advances, and challenges , 2021, IEEE Signal Processing Magazine.

[7]  Mingliang Tao,et al.  Automatic Modulation Recognition Based on Adaptive Attention Mechanism and ResNeXt WSL Model , 2021, IEEE Communications Letters.

[8]  Liang Liu,et al.  Multitask-Learning-Based Deep Neural Network for Automatic Modulation Classification , 2021, IEEE Internet of Things Journal.

[9]  Humphrey Shi,et al.  Escaping the Big Data Paradigm with Compact Transformers , 2021, ArXiv.

[10]  Saining Xie,et al.  An Empirical Study of Training Self-Supervised Vision Transformers , 2021, 2021 IEEE/CVF International Conference on Computer Vision (ICCV).

[11]  Matthijs Douze,et al.  LeViT: a Vision Transformer in ConvNet’s Clothing for Faster Inference , 2021, 2021 IEEE/CVF International Conference on Computer Vision (ICCV).

[12]  Yihong Dong,et al.  SSRCNN: A Semi-Supervised Learning Framework for Signal Recognition , 2021, IEEE Transactions on Cognitive Communications and Networking.

[13]  Zenglin Xu,et al.  A Survey on Deep Semi-Supervised Learning , 2021, IEEE Transactions on Knowledge and Data Engineering.

[14]  Fillia Makedon,et al.  A Survey on Contrastive Self-supervised Learning , 2020, Technologies.

[15]  S. Gelly,et al.  An Image is Worth 16x16 Words: Transformers for Image Recognition at Scale , 2020, ICLR.

[16]  Brian Kenji Iwana,et al.  An empirical survey of data augmentation for time series classification with neural networks , 2020, PloS one.

[17]  Pierre H. Richemond,et al.  Bootstrap Your Own Latent: A New Approach to Self-Supervised Learning , 2020, NeurIPS.

[18]  Kaiming He,et al.  Improved Baselines with Momentum Contrastive Learning , 2020, ArXiv.

[19]  Geoffrey E. Hinton,et al.  A Simple Framework for Contrastive Learning of Visual Representations , 2020, ICML.

[20]  Liang Huang,et al.  Data Augmentation for Deep Learning-Based Radio Modulation Classification , 2019, IEEE Access.

[21]  Ross B. Girshick,et al.  Momentum Contrast for Unsupervised Visual Representation Learning , 2019, 2020 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR).

[22]  Xiaofan Li,et al.  A Survey on Deep Learning Techniques in Wireless Signal Recognition , 2019, Wirel. Commun. Mob. Comput..

[23]  Yonina C. Eldar,et al.  Fast Deep Learning for Automatic Modulation Classification , 2019, ArXiv.

[24]  Yifan Wu,et al.  Radio Classify Generative Adversarial Networks: A Semi-supervised Method for Modulation Recognition , 2018, 2018 IEEE 18th International Conference on Communication Technology (ICCT).

[25]  Stella X. Yu,et al.  Unsupervised Feature Learning via Non-parametric Instance Discrimination , 2018, 2018 IEEE/CVF Conference on Computer Vision and Pattern Recognition.

[26]  Ingrid Moerman,et al.  End-to-End Learning From Spectrum Data: A Deep Learning Approach for Wireless Signal Identification in Spectrum Monitoring Applications , 2017, IEEE Access.

[27]  Gang Sun,et al.  Squeeze-and-Excitation Networks , 2017, 2018 IEEE/CVF Conference on Computer Vision and Pattern Recognition.

[28]  Sofie Pollin,et al.  Deep Learning Models for Wireless Signal Classification With Distributed Low-Cost Spectrum Sensors , 2017, IEEE Transactions on Cognitive Communications and Networking.

[29]  Lukasz Kaiser,et al.  Attention is All you Need , 2017, NIPS.

[30]  Dana Kulic,et al.  Data augmentation of wearable sensor data for parkinson’s disease monitoring using convolutional neural networks , 2017, ICMI.

[31]  T. Charles Clancy,et al.  Convolutional Radio Modulation Recognition Networks , 2016, EANN.

[32]  Aaron C. Courville,et al.  Generative Adversarial Nets , 2014, NIPS.

[33]  Pierre Baldi,et al.  Autoencoders, Unsupervised Learning, and Deep Architectures , 2011, ICML Unsupervised and Transfer Learning.

[34]  Yupei Zhang,et al.  Limited Data Spectrum Sensing Based on Semi-Supervised Deep Neural Network , 2021, IEEE Access.

[35]  Wei Hong Lim,et al.  Machine Learning Based Automatic Modulation Recognition for Wireless Communications: A Comprehensive Survey , 2021, IEEE Access.

[36]  RUOLIN ZHOU,et al.  Deep Learning for Modulation Recognition: A Survey With a Demonstration , 2020, IEEE Access.

[37]  Rui Dai,et al.  Automatic Modulation Classification Using Gated Recurrent Residual Network , 2020, IEEE Internet Things J..