Abstract
Modulation recognition of communication signals plays an important role in both civil and military uses. Neural network-based modulation recognition methods can extract high-level abstract features which can be adopted for classification of modulation types. Compared with traditional recognition methods based on manually defined features, they have the advantage of higher recognition rate. However, in actual modulation recognition scenarios, due to inaccurate estimation of receiving parameters and other reasons, the input signal samples for modulation recognition may have large phase, frequency offsets, and time scale changes. Existing deep learning-based modulation recognition methods have not considered the influences brought by the above issues, thus resulting in a decreased recognition rate. A modulation recognition method based on the spatial transformation network is proposed in this paper. In the proposed network, some prior models for synchronization in communication are introduced, and the priori models are realized through the spatial transformation subnetwork, so as to reduce the influence of phase, frequency offsets, and time scale differences. Experiments on simulated datasets prove that compared with the traditional CNN, ResNet, and the CLDNN, the recognition rate of the proposed method has increased by 8.0%, 5.8%, and 4.6%, respectively, when the signal-to-noise ratio is greater than 0. Moreover, the proposed network is also easier to train. The training time required for convergence has reduced by 4.5% and 80.7% compared to the ResNet and CLDNN, respectively.
Highlights
Modulation recognition of communication signals plays an important role in both civil and military applications
For real scenario modulation recognition applications, signals of the same modulation type may have encountered the effects of different time scales and frequency offsets
A modulation recognition method based on spatial transformation network is proposed in this paper
Summary
Modulation recognition of communication signals plays an important role in both civil and military applications. Deep learning-based methods have shortcomings, such as the lack of interpretability of features and the inability to estimate signal parameters, such as symbol rate, in the process of modulation recognition. From the aforementioned modulation recognition methods, the influence of different symbol rates, frequencies, and phase offsets is eliminated through the receiving synchronization process under both cooperative communication condition and blind receiving condition. In real application, due to the inaccurate estimation of blind receiving parameters, the input signal samples for modulation recognition still have large phase and frequency offsets and different time scales. Assuming that the processing of the above formula is complex value based, where xin is the input and xout is the output, the parameter θ4 represents the frequency offset estimation, the parameter θ5 represents the phase offset estimation, and n represents the time. Adopting the estimation of n, the relative SPS can be estimated according to the original samples
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