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利用边缘设备上的轻量级卷积神经网络架构和 Grad-CAM 进行实时葡萄叶疾病分类,以提高农业水平。

Enhancing agriculture through real-time grape leaf disease classification via an edge device with a lightweight CNN architecture and Grad-CAM.

机构信息

Department of Electrical & Computer Engineering, Rajshahi University of Engineering & Technology, Rajshahi, 6204, Bangladesh.

Department of Computer Science, University of York, Deramore Lane, Heslington, York, YO10 5GH, UK.

出版信息

Sci Rep. 2024 Jul 11;14(1):16022. doi: 10.1038/s41598-024-66989-9.

DOI:10.1038/s41598-024-66989-9
PMID:38992069
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11239930/
Abstract

Crop diseases can significantly affect various aspects of crop cultivation, including crop yield, quality, production costs, and crop loss. The utilization of modern technologies such as image analysis via machine learning techniques enables early and precise detection of crop diseases, hence empowering farmers to effectively manage and avoid the occurrence of crop diseases. The proposed methodology involves the use of modified MobileNetV3Large model deployed on edge device for real-time monitoring of grape leaf disease while reducing computational memory demands and ensuring satisfactory classification performance. To enhance applicability of MobileNetV3Large, custom layers consisting of two dense layers were added, each followed by a dropout layer, helped mitigate overfitting and ensured that the model remains efficient. Comparisons among other models showed that the proposed model outperformed those with an average train and test accuracy of 99.66% and 99.42%, with a precision, recall, and F1 score of approximately 99.42%. The model was deployed on an edge device (Nvidia Jetson Nano) using a custom developed GUI app and predicted from both saved and real-time data with high confidence values. Grad-CAM visualization was used to identify and represent image areas that affect the convolutional neural network (CNN) classification decision-making process with high accuracy. This research contributes to the development of plant disease classification technologies for edge devices, which have the potential to enhance the ability of autonomous farming for farmers, agronomists, and researchers to monitor and mitigate plant diseases efficiently and effectively, with a positive impact on global food security.

摘要

作物病害会严重影响作物种植的各个方面,包括作物产量、质量、生产成本和作物损失。利用机器学习技术的图像分析等现代技术,可以实现作物病害的早期、准确检测,从而使农民能够有效地管理和避免作物病害的发生。该方法使用经过修改的 MobileNetV3Large 模型在边缘设备上部署,用于实时监测葡萄叶病害,同时减少计算内存需求并确保令人满意的分类性能。为了增强 MobileNetV3Large 的适用性,添加了由两个密集层组成的自定义层,每个层后面都有一个 dropout 层,有助于减轻过拟合并确保模型保持高效。与其他模型的比较表明,所提出的模型的平均训练和测试准确率为 99.66%和 99.42%,精度、召回率和 F1 得分约为 99.42%,优于其他模型。该模型已在边缘设备(Nvidia Jetson Nano)上使用自定义开发的 GUI 应用程序进行部署,并使用保存的数据和实时数据进行预测,置信度值较高。梯度 CAM 可视化用于识别和表示影响卷积神经网络(CNN)分类决策过程的图像区域,具有较高的准确性。这项研究为边缘设备上的植物病害分类技术的发展做出了贡献,这有可能增强农民、农学家和研究人员的自主农业能力,有效地监测和减轻植物病害,对全球粮食安全产生积极影响。

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Comput Intell Neurosci. 2022 Apr 5;2022:6504616. doi: 10.1155/2022/6504616. eCollection 2022.
3
Design and optimization of a TensorFlow Lite deep learning neural network for human activity recognition on a smartphone.
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Plants (Basel). 2025 Jun 11;14(12):1794. doi: 10.3390/plants14121794.
4
Application of Convolutional Neural Networks and Recurrent Neural Networks in Food Safety.卷积神经网络和循环神经网络在食品安全中的应用。
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5
A high-throughput ResNet CNN approach for automated grapevine leaf hair quantification.一种用于自动量化葡萄叶片绒毛的高通量残差神经网络卷积神经网络方法。
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4
Fine-Grained Grape Leaf Diseases Recognition Method Based on Improved Lightweight Attention Network.基于改进轻量级注意力网络的细粒度葡萄叶病害识别方法
Front Plant Sci. 2021 Oct 22;12:738042. doi: 10.3389/fpls.2021.738042. eCollection 2021.
5
Plant health and its effects on food safety and security in a One Health framework: four case studies.“同一健康”框架下的植物健康及其对食品安全和保障的影响:四个案例研究
One Health Outlook. 2021 Mar 31;3:6. doi: 10.1186/s42522-021-00038-7. eCollection 2021.
6
Combining Biocontrol Agents with Chemical Fungicides for Integrated Plant Fungal Disease Control.将生物防治剂与化学杀菌剂结合用于植物真菌病害的综合防治。
Microorganisms. 2020 Dec 4;8(12):1930. doi: 10.3390/microorganisms8121930.
7
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