Fully Dense Neural Network for the Automatic Modulation Recognition

Nowadays, we mainly use various convolution neural network (CNN) structures to extract features from radio data or spectrogram in AMR. Based on expert experience and spectrograms, they not only increase the difficulty of preprocessing, but also consume a lot of memory. In order to directly use in-ph...

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Veröffentlicht in:	arXiv.org 2019-12
Hauptverfasser:	Du, Miao, Yu, Qin, Shaomin Fei, Wang, Chen, Gong, Xiaofeng, Luo, Ruisen
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Sprache:	eng
Schlagworte:	Artificial neural networks Automatic modulation recognition Convolution Feature extraction Feature recognition Machine learning Neural networks Quadratures Spectrograms
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creator	Du, Miao Yu, Qin Shaomin Fei Wang, Chen Gong, Xiaofeng Luo, Ruisen
description	Nowadays, we mainly use various convolution neural network (CNN) structures to extract features from radio data or spectrogram in AMR. Based on expert experience and spectrograms, they not only increase the difficulty of preprocessing, but also consume a lot of memory. In order to directly use in-phase and quadrature (IQ) data obtained by the receiver and enhance the efficiency of network extraction features to improve the recognition rate of modulation mode, this paper proposes a new network structure called Fully Dense Neural Network (FDNN). This network uses residual blocks to extract features, dense connect to reduce model size, and adds attentions mechanism to recalibrate. Experiments on RML2016.10a show that this network has a higher recognition rate and lower model complexity. And it shows that the FDNN model with dense connections can not only extract features effectively but also greatly reduce model parameters, which also provides a significant contribution for the application of deep learning to the intelligent radio system.
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subjects	Artificial neural networks Automatic modulation recognition Convolution Feature extraction Feature recognition Machine learning Neural networks Quadratures Spectrograms
title	Fully Dense Neural Network for the Automatic Modulation Recognition
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