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通过基于计算机视觉的非侵入式粪便分类实现家禽早期健康预测

Towards Early Poultry Health Prediction through Non-Invasive and Computer Vision-Based Dropping Classification.

作者信息

Nakrosis Arnas, Paulauskaite-Taraseviciene Agne, Raudonis Vidas, Narusis Ignas, Gruzauskas Valentas, Gruzauskas Romas, Lagzdinyte-Budnike Ingrida

机构信息

Faculty of Informatics, Kaunas University of Technology, Studentu 50, 51368 Kaunas, Lithuania.

Artificial Intelligence Centre, Kaunas University of Technology, K. Barsausko 59, 51423 Kaunas, Lithuania.

出版信息

Animals (Basel). 2023 Sep 27;13(19):3041. doi: 10.3390/ani13193041.

DOI:10.3390/ani13193041
PMID:37835647
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10571708/
Abstract

The use of artificial intelligence techniques with advanced computer vision techniques offers great potential for non-invasive health assessments in the poultry industry. Evaluating the condition of poultry by monitoring their droppings can be highly valuable as significant changes in consistency and color can be indicators of serious and infectious diseases. While most studies have prioritized the classification of droppings into two categories (normal and abnormal), with some relevant studies dealing with up to five categories, this investigation goes a step further by employing image processing algorithms to categorize droppings into six classes, based on visual information indicating some level of abnormality. To ensure a diverse dataset, data were collected in three different poultry farms in Lithuania by capturing droppings on different types of litter. With the implementation of deep learning, the object detection rate reached 92.41% accuracy. A range of machine learning algorithms, including different deep learning architectures, has been explored and, based on the obtained results, we have proposed a comprehensive solution by combining different models for segmentation and classification purposes. The results revealed that the segmentation task achieved the highest accuracy of 0.88 in terms of the Dice coefficient employing the K-means algorithm. Meanwhile, YOLOv5 demonstrated the highest classification accuracy, achieving an ACC of 91.78%.

摘要

将人工智能技术与先进的计算机视觉技术相结合,在家禽行业的非侵入性健康评估方面具有巨大潜力。通过监测家禽粪便来评估其健康状况可能非常有价值,因为粪便的稠度和颜色的显著变化可能是严重疾病和传染病的指标。虽然大多数研究将粪便分类为两类(正常和异常),一些相关研究处理多达五类,但本研究更进一步,通过使用图像处理算法,根据表明某种程度异常的视觉信息将粪便分为六类。为确保数据集的多样性,在立陶宛的三个不同家禽养殖场收集数据,在不同类型的垫料上采集粪便。通过实施深度学习,目标检测准确率达到92.41%。我们探索了一系列机器学习算法,包括不同的深度学习架构,并根据所得结果,为分割和分类目的结合不同模型提出了一个综合解决方案。结果显示,采用K均值算法,分割任务在Dice系数方面达到了最高准确率0.88。同时,YOLOv5展示了最高的分类准确率,ACC达到91.78%。

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