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YOLO-TPS:一种用于复杂水产养殖环境的多模块协同高精度鱼类疾病检测模型。

YOLO-TPS: A Multi-Module Synergistic High-Precision Fish-Disease Detection Model for Complex Aquaculture Environments.

作者信息

Ouyang Cheng, Peng Hao, Tan Mingyu, Yang Lin, Deng Jingtao, Jiang Pin, Hu Wenwu, Wang Yi

机构信息

College of Information and Intelligence, Hunan Agricultural University, Changsha 410128, China.

College of Mechanical and Electrical Engineering, Hunan Agricultural University, Changsha 410128, China.

出版信息

Animals (Basel). 2025 Aug 11;15(16):2356. doi: 10.3390/ani15162356.

DOI:10.3390/ani15162356
PMID:40867684
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12383064/
Abstract

Fish are a vital aquatic resource worldwide, and the sustainable development of aquaculture is essential for global food security and economic growth. However, the high incidence of fish diseases in complex aquaculture environments significantly hampers sustainability, and traditional manual diagnosis methods are inefficient and often inaccurate. To address the challenges of small-lesion detection, lesion area size and morphological variation, and background complexity, we propose YOLO-TPS, a high-precision fish-disease detection model based on an improved YOLOv11n architecture. The model integrates a multi-module synergy strategy and a triple-attention mechanism to enhance detection performance. Specifically, the SPPF_TSFA module is introduced into the backbone to fuse spatial, channel, and neuron-level attention for better multi-scale feature extraction of early-stage lesions. A PC_Shuffleblock module incorporating asymmetric pinwheel-shaped convolutions is embedded in the detection head to improve spatial awareness and texture modeling under complex visual conditions. Additionally, a scale-aware dynamic intersection over union (SDIoU) loss function was designed to accommodate changes in the scale and morphology of lesions at different stages of the disease. Experimental results on a dataset comprising 4596 images across six fish-disease categories demonstrate superior performance (mAP: 97.2%, Precision: 97.9%, Recall: 95.1%) compared to the baseline. This study offers a robust, scalable solution for intelligent fish-disease diagnosis and has promising implications for sustainable aquaculture and animal health monitoring.

摘要

鱼类是全球重要的水生资源,水产养殖的可持续发展对全球粮食安全和经济增长至关重要。然而,复杂水产养殖环境中鱼类疾病的高发病率严重阻碍了可持续性,传统的人工诊断方法效率低下且往往不准确。为应对小病灶检测、病灶面积大小和形态变化以及背景复杂性等挑战,我们提出了YOLO-TPS,一种基于改进的YOLOv11n架构的高精度鱼类疾病检测模型。该模型集成了多模块协同策略和三重注意力机制以提高检测性能。具体而言,在主干网络中引入了SPPF_TSFA模块,融合空间、通道和神经元级注意力,以便更好地对早期病灶进行多尺度特征提取。在检测头中嵌入了一个包含非对称风车形卷积的PC_Shuffleblock模块,以提高复杂视觉条件下的空间感知和纹理建模能力。此外,设计了一种尺度感知动态交并比(SDIoU)损失函数,以适应疾病不同阶段病灶的尺度和形态变化。在一个包含六个鱼类疾病类别的4596张图像的数据集上的实验结果表明,与基线相比,该模型具有卓越的性能(平均精度均值:97.2%,精确率:97.9%,召回率:95.1%)。本研究为智能鱼类疾病诊断提供了一种强大、可扩展的解决方案,对可持续水产养殖和动物健康监测具有广阔的应用前景。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d9e5/12383064/ed4091558f57/animals-15-02356-g013.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d9e5/12383064/fe10a68e5078/animals-15-02356-g007.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d9e5/12383064/e2bcc2d2eda2/animals-15-02356-g008.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d9e5/12383064/565fb8ef94d0/animals-15-02356-g009.jpg
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