AI Article Synopsis
- Underwater acoustic target recognition faces challenges like limited labeled data, complex marine environments, and background noise interference, making it a complicated task.!* -
- The proposed solution, AResnet, uses an attention-based residual network to extract and enhance features for identifying ship-radiated noise across various settings.!* -
- Testing on two datasets, the DeepShip dataset achieved a 99% recognition accuracy, while the ShipsEar dataset yielded a 98% accuracy, outperforming comparison methods.!*
Article Abstract
Underwater acoustic target recognition is very complex due to the lack of labeled data sets, the complexity of the marine environment, and the interference of background noise. In order to enhance it, we propose an attention-based residual network recognition method (AResnet). The method can be used to identify ship-radiated noise in different environments. Firstly, a residual network is used to extract the deep abstract features of three-dimensional fusion features, and then a channel attention module is used to enhance different channels. Finally, the features are classified by the joint supervision of cross-entropy and central loss functions. At the same time, for the recognition of ship-radiated noise in other environments, we use the pre-training network AResnet to extract the deep acoustic features and apply the network structure to underwater acoustic target recognition after fine-tuning. The two sets of ship radiation noise datasets are verified, the DeepShip dataset is trained and verified, and the average recognition accuracy is 99%. Then, the trained AResnet structure is fine-tuned and applied to the ShipsEar dataset. The average recognition accuracy is 98%, which is better than the comparison method.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9688950 | PMC |
| http://dx.doi.org/10.3390/e24111657 | DOI Listing |
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