BGLE-YOLO: A Lightweight Model for Underwater Bio-Detection

BGLE-YOLO: A Lightweight Model for Underwater Bio-Detection

Due to low contrast, chromatic aberration, and generally small objects in underwater environments, a new underwater fish detection model, BGLE-YOLO, is proposed to investigate automated methods dedicated to accurately detecting underwater objects in images. The model has small parameters and low com...

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Bibliographic Details
Main Authors: Hua Zhao, Chao Xu, Jiaxing Chen, Zhexian Zhang, Xiang Wang
Format: Article
Language:English
Published: MDPI AG 2025-03-01
Series:Sensors
Subjects:
underwater fish detection
BGLE-YOLO
YOLOv8
multi-scale feature fusion
lightweight model
Online Access:https://www.mdpi.com/1424-8220/25/5/1595
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Summary:Due to low contrast, chromatic aberration, and generally small objects in underwater environments, a new underwater fish detection model, BGLE-YOLO, is proposed to investigate automated methods dedicated to accurately detecting underwater objects in images. The model has small parameters and low computational effort and is suitable for edge devices. First, an efficient multi-scale convolutional EMC module is introduced to enhance the backbone network and capture the dynamic changes in targets in the underwater environment. Secondly, a global and local feature fusion module for small targets (BIG) is integrated into the neck network to preserve more feature information, reduce error information in higher-level features, and increase the model’s effectiveness in detecting small targets. Finally, to prevent the detection accuracy impact due to excessive lightweighting, the lightweight shared head (LSH) is constructed. The reparameterization technique further improves detection accuracy without additional parameters and computational cost. Experimental results of BGLE-YOLO on the underwater datasets DUO (Detection Underwater Objects) and RUOD (Real-World Underwater Object Detection) show that the model achieves the same accuracy as the benchmark model with an ultra-low computational cost of 6.2 GFLOPs and an ultra-low model parameter of 1.6 MB.
ISSN:1424-8220

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