Abstract
Blind detection of underwater acoustic communication (UWAC) signals is challenging in non-cooperative reception scenarios. Difficulties include but not limited to complex underwater acoustic channels, diversity of signal categories, and data scarcity. To address these problems, we propose a novel blind detection method for UWAC signals based on deep learning (DL). First, an impulsive noise preprocessor and a signal denoising generative adversarial network are built to mitigate the noise in the received signals. Second, a convolutional neural network-based binary classification network is built to automatically extract features and distinguish between the UWAC signals and noise. Moreover, a transfer data model is presented to overcome the insufficient data issue in the target water regions. The results of simulation experiments and practical signal tests both demonstrate that the proposed method is robust to ambient noise with wide dynamic ranges and complex distributions. Our approach significantly outperforms conventional algorithms and existing DL-based algorithms at low signal-to-noise ratios, while requiring no prior information about the testing channel.
Highlights
Blind detection of underwater acoustic communication (UWAC) signals involves determining whether an observed underwater acoustic signal is a communication signal or ambient noise without any prior information
The offline training is implemented on the transferred training set, which is based on the transfer data model expressed in (16). is randomly selected in the range of [1.5, 2], with mixed signal-tonoise ratio (MSNR) in the range of [−10, 10] dB
There is still a gain of 3 dB compared with the soft limiter detector (SLD) approach, indicating that the signal denoising generative adversarial network (SDGAN) itself has the capability to adapt to weak impulsive noise
Summary
Blind detection of underwater acoustic communication (UWAC) signals involves determining whether an observed underwater acoustic signal is a communication signal or ambient noise without any prior information. This task plays an important role in the modulation classification and information recovery of UWAC signals in non-cooperative reception scenarios. The spectrums of different UWAC signals vary significantly with complex structural characteristics. Due to the lack of prior information under complex marine environments, the aforementioned methods are inapplicable to non-cooperative UWAC signals. There are multiple UWAC signals with different features This increases the complexity of the feature-based approach for large signal sets
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