Automatic Modulation Classification Under Non-Gaussian Noise: A Deep Residual Learning Approach

During the last few years, automatic modulation classification (AMC) has attracted widespread attention in both civilian and military applications. Conventional AMC schemes are primarily developed under Gaussian noise assumptions. However, recent empirical studies show that non-Gaussian noise has emerged in a variety of wireless networked systems. The bursty nature of non-Gaussian noise fundamentally challenges the applicability of the conventional AMC schemes. In order to improve the classification performance under non-Gaussian noise, in this paper, a novel modulation classification method is proposed by using cyclic correntropy spectrum (CCES) and deep residual neural network (ResNet). First, CCES is introduced to effectively suppress non-Gaussian noise through the designated Gaussian kernel. CCES also provides significantly different CCES graphs with respect to different modulation schemes, enabling AMC to directly operate with the graphs without further feature extraction. Next, based on the CCES graphs, an end-to-end deep ResNet-based AMC is developed to recognize the correct modulation by iteratively evaluating the residual information in a cascade of multiple learning layers. Experimental results confirm that the proposed algorithm outperforms existing designs with much higher classification accuracy, i.e., 3 dB less in the required generalized signal to noise ratio for 100% accuracy, in non-Gaussian noise environments.

[1]  Ali Abdi,et al.  Survey of automatic modulation classification techniques: classical approaches and new trends , 2007, IET Commun..

[2]  Rong Li,et al.  Variable step-size modified blind equalization algorithm based on fractional lower order statistics under impulsive noise , 2017, 2017 3rd IEEE International Conference on Computer and Communications (ICCC).

[3]  Jian Sun,et al.  Deep Residual Learning for Image Recognition , 2015, 2016 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[4]  Jinfeng Zhang,et al.  A novel correntropy based DOA estimation algorithm in impulsive noise environments , 2014, Signal Process..

[5]  Asoke K. Nandi,et al.  Automatic Modulation Classification Using Combination of Genetic Programming and KNN , 2012, IEEE Transactions on Wireless Communications.

[6]  Tao Liu,et al.  Cyclic Correntropy: Foundations and Theories , 2018, IEEE Access.

[7]  Ian F. Akyildiz,et al.  Magnetic Induction-Based Localization in Randomly Deployed Wireless Underground Sensor Networks , 2017, IEEE Internet of Things Journal.

[8]  Fanggang Wang,et al.  Fast and Robust Modulation Classification via Kolmogorov-Smirnov Test , 2010, IEEE Transactions on Communications.

[9]  Ling Yu,et al.  Cyclic correntropy and its spectrum in frequency estimation in the presence of impulsive noise , 2016, Signal Process..

[10]  Titir Dutta,et al.  A novel method for automatic modulation classification under non-Gaussian noise based on variational mode decomposition , 2016, 2016 Twenty Second National Conference on Communication (NCC).

[11]  Ian F. Akyildiz,et al.  5G roadmap: 10 key enabling technologies , 2016, Comput. Networks.

[12]  Claudio R. C. M. da Silva,et al.  Classification of Digital Amplitude-Phase Modulated Signals in Time-Correlated Non-Gaussian Channels , 2013, IEEE Transactions on Communications.

[13]  Tianshuang Qiu,et al.  Automatic Modulation Classification Using Cyclic Correntropy Spectrum in Impulsive Noise , 2019, IEEE Wireless Communications Letters.