增强番茄植株上 Tuta absoluta 的检测:集合技术和深度学习

AI Pub Date : 2023-11-20 DOI:10.3390/ai4040050
Nikolaos Giakoumoglou, E. Pechlivani, Nikolaos Frangakis, Dimitrios Tzovaras
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摘要

及早发现并采取有效的管理措施控制 Tuta absoluta (Meyrick) 侵害对保障番茄产量和减少经济损失至关重要。本研究采用对象检测模型与集合技术相结合,对番茄植株上的 T. absoluta 侵害进行了检测。此外,本研究还强调了利用在露天田地和温室环境中采集的真实数据集来解决植物健康场景中物体检测所面临的复杂现实挑战的重要性。评估了基于深度学习的模型(包括 Faster R-CNN 和 RetinaNet)在检测 T. absoluta 损害方面的有效性。最初的模型评估显示,在不同的模型配置(包括不同的骨干和头部)下,性能水平都在下降。为了增强检测预测并提高平均精度(mAP)分数,应用了集合技术,如非最大值抑制(NMS)、软性非最大值抑制(Soft NMS)、非最大值加权(NMW)和加权盒融合(WBF)。结果显示,WBF 技术显著提高了 mAP 分数,从 0.58(单个模型的最大 mAP)提高到 0.70,提高了 20%。本研究的结果强调了深度学习和集合技术在提高物体检测模型的准确性和可靠性方面的潜力,从而为农业害虫检测领域做出了贡献。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Enhancing Tuta absoluta Detection on Tomato Plants: Ensemble Techniques and Deep Learning
Early detection and efficient management practices to control Tuta absoluta (Meyrick) infestation is crucial for safeguarding tomato production yield and minimizing economic losses. This study investigates the detection of T. absoluta infestation on tomato plants using object detection models combined with ensemble techniques. Additionally, this study highlights the importance of utilizing a dataset captured in real settings in open-field and greenhouse environments to address the complexity of real-life challenges in object detection of plant health scenarios. The effectiveness of deep-learning-based models, including Faster R-CNN and RetinaNet, was evaluated in terms of detecting T. absoluta damage. The initial model evaluations revealed diminishing performance levels across various model configurations, including different backbones and heads. To enhance detection predictions and improve mean Average Precision (mAP) scores, ensemble techniques were applied such as Non-Maximum Suppression (NMS), Soft Non-Maximum Suppression (Soft NMS), Non-Maximum Weighted (NMW), and Weighted Boxes Fusion (WBF). The outcomes shown that the WBF technique significantly improved the mAP scores, resulting in a 20% improvement from 0.58 (max mAP from individual models) to 0.70. The results of this study contribute to the field of agricultural pest detection by emphasizing the potential of deep learning and ensemble techniques in improving the accuracy and reliability of object detection models.
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