Detection of cotton leaf curl disease’s susceptibility scale level based on deep learning

Rubaina Nazeer, Sajid Ali, Zhihua Hu, Ghulam Jillani Ansari, Muna Al-Razgan, Emad Mahrous Awwad, Yazeed Yasin Ghadi
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Abstract

Cotton, a crucial cash crop in Pakistan, faces persistent threats from diseases, notably the Cotton Leaf Curl Virus (CLCuV). Detecting these diseases accurately and early is vital for effective management. This paper offers a comprehensive account of the process involved in collecting, preprocessing, and analyzing an extensive dataset of cotton leaf images. The primary aim of this dataset is to support automated disease detection systems. We delve into the data collection procedure, distribution of the dataset, preprocessing stages, feature extraction methods, and potential applications. Furthermore, we present the preliminary findings of our analyses and emphasize the significance of such datasets in advancing agricultural technology. The impact of these factors on plant growth is significant, but the intrusion of plant diseases, such as Cotton Leaf Curl Disease (CLCuD) caused by the Cotton Leaf Curl Gemini Virus (CLCuV), poses a substantial threat to cotton yield. Identifying CLCuD promptly, especially in areas lacking critical infrastructure, remains a formidable challenge. Despite the substantial research dedicated to cotton leaf diseases in agriculture, deep learning technology continues to play a vital role across various sectors. In this study, we harness the power of two deep learning models, specifically the Convolutional Neural Network (CNN). We evaluate these models using two distinct datasets: one from the publicly available Kaggle dataset and the other from our proprietary collection, encompassing a total of 1349 images capturing both healthy and disease-affected cotton leaves. Our meticulously curated dataset is categorized into five groups: Healthy, Fully Susceptible, Partially Susceptible, Fully Resistant, and Partially Resistant. Agricultural experts annotated our dataset based on their expertise in identifying abnormal growth patterns and appearances. Data augmentation enhances the precision of model performance, with deep features extracted to support both training and testing efforts. Notably, the CNN model outperforms other models, achieving an impressive accuracy rate of 99% when tested against our proprietary dataset.
基于深度学习的棉花卷叶病易感尺度等级检测
棉花是巴基斯坦的一种重要经济作物,但它一直面临着病害的威胁,尤其是棉花卷叶病毒(CLCuV)。准确、及早地检测这些病害对于有效管理至关重要。本文全面介绍了收集、预处理和分析大量棉花叶片图像数据集的过程。该数据集的主要目的是支持自动病害检测系统。我们深入探讨了数据收集程序、数据集的分布、预处理阶段、特征提取方法和潜在应用。此外,我们还介绍了分析的初步结果,并强调了此类数据集在推动农业技术发展方面的重要意义。这些因素对植物生长的影响很大,但植物病害的入侵,如棉花卷叶双子座病毒(CLCuV)引起的棉花卷叶病(CLCuD),对棉花产量构成了巨大威胁。及时发现 CLCuD 仍是一项艰巨的挑战,尤其是在缺乏关键基础设施的地区。尽管对农业中的棉叶病害进行了大量研究,但深度学习技术仍在各个领域发挥着重要作用。在本研究中,我们利用了两种深度学习模型的力量,特别是卷积神经网络(CNN)。我们使用两个不同的数据集对这些模型进行了评估:一个数据集来自公开的 Kaggle 数据集,另一个数据集来自我们专有的数据集,共包含 1349 张捕捉健康和受疾病影响的棉花叶片的图像。我们精心策划的数据集分为五组:健康组、完全易感组、部分易感组、完全抗病组和部分抗病组。农业专家根据他们在识别异常生长模式和外观方面的专业知识对我们的数据集进行了注释。通过提取深度特征来支持训练和测试工作,数据增强提高了模型性能的精度。值得注意的是,CNN 模型的表现优于其他模型,在对我们的专有数据集进行测试时,准确率达到了令人印象深刻的 99%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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