Enhancing Underwater Video from Consecutive Frames While Preserving Temporal Consistency

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Detalles Bibliográficos
Publicado en:	Journal of Marine Science and Engineering vol. 13, no. 1 (2025), p. 127
Autor principal:	Hu, Kai
Otros Autores:	Meng, Yuancheng, Liao, Zichen, Tang, Lei, Ye, Xiaoling
Publicado:	MDPI AG
Materias:	Consistency Deep learning Frames (data processing) Image enhancement Lighting Video recordings Optical flow (image analysis) Task complexity Feature maps Methods Information processing Modules Image quality Research & development > R&D Underwater Environmental
Acceso en línea:	Citation/Abstract Full Text + Graphics Full Text - PDF
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Descripción
Resumen:	Current methods for underwater image enhancement primarily focus on single-frame processing. While these approaches achieve impressive results for static images, they often fail to maintain temporal coherence across frames in underwater videos, which leads to temporal artifacts and frame flickering. Furthermore, existing enhancement methods struggle to accurately capture features in underwater scenes. This makes it difficult to handle challenges such as uneven lighting and edge blurring in complex underwater environments. To address these issues, this paper presents a dual-branch underwater video enhancement network. The network synthesizes short-range video sequences by learning and inferring optical flow from individual frames. It effectively enhances temporal consistency across video frames through predicted optical flow information, thereby mitigating temporal instability within frame sequences. In addition, to address the limitations of traditional U-Net models in handling complex multiscale feature fusion, this study proposes a novel underwater feature fusion module. By applying both max pooling and average pooling, this module separately extracts local and global features. It utilizes an attention mechanism to adaptively adjust the weights of different regions in the feature map, thereby effectively enhancing key regions within underwater video frames. Experimental results indicate that when compared with the existing underwater image enhancement baseline method and the consistency enhancement baseline method, the proposed model improves the consistency index by 30% and shows a marginal decrease of only 0.6% in enhancement quality index, demonstrating its superiority in underwater video enhancement tasks.
ISSN:	2077-1312
DOI:	10.3390/jmse13010127
Fuente:	Engineering Database