Underwater Reverberation Suppression Using Wavelet Transform and Complementary Learning

Underwater Reverberation Suppression Using Wavelet Transform and Complementary Learning

Reverberation is the primary interference of active detection. Therefore, the effective suppression of reverberation is a prerequisite for reliable signal processing. Existing dereverberation methods have shown effectiveness in specific scenarios. However, they often struggle to exploit the distinct...

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Bibliographic Details
Main Authors: Jiajie Liu, Qunfei Zhang, Xiaodong Cui, Chencong Tang, Zijun Pu
Format: Article
Language:English
Published: MDPI AG 2025-06-01
Series:Oceans
Subjects:
reverberation suppression
complementary learning
Continuous Wavelet Transform
attentional mechanisms
Online Access:https://www.mdpi.com/2673-1924/6/2/36
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Summary:Reverberation is the primary interference of active detection. Therefore, the effective suppression of reverberation is a prerequisite for reliable signal processing. Existing dereverberation methods have shown effectiveness in specific scenarios. However, they often struggle to exploit the distinction between target echo and reverberation, especially in complex, dynamically changing underwater environments. This paper proposes a novel dereverberation network, ERCL-AttentionNet (Echo–Reverberation Complementary Learning Attention Network). We use the Continuous Wavelet Transform (CWT) to extract time–frequency features from the received signal, effectively balancing the time and frequency resolution. The real and imaginary parts of the time–frequency matrix are combined to generate attention representations, which are processed by the network. The network architecture consists of two complementary UNet models sharing the same encoder. These models independently learn target echo and reverberation features to reconstruct the target echo. An attention mechanism further enhances performance by focusing on target information and suppressing irrelevant disturbances in complex environments. Experimental results demonstrate that our method achieves a higher Peak-to-Average Signal-to-Reverberation Ratio (PSRR), Structural Similarity Index (SSIM), and Peak-to-Average Ratio (PAR) of cross-correlation while effectively preserving key time–frequency features, compared to traditional methods such as autoregressive (AR) and singular value decomposition (SVD).
ISSN:2673-1924

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