机器学习用于植物病害检测的交叉比较综述:苹果、木薯、棉花和马铃薯植物

IF 8.2 Q1 AGRICULTURE, MULTIDISCIPLINARY Artificial Intelligence in Agriculture Pub Date : 2024-06-01 DOI:10.1016/j.aiia.2024.04.002
James Daniel Omaye , Emeka Ogbuju , Grace Ataguba , Oluwayemisi Jaiyeoba , Joseph Aneke , Francisca Oladipo
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引用次数: 0

摘要

植物病害检测在防治对全球农业和粮食安全构成威胁的植物病害方面发挥了重要作用。及早发现这些病害有助于减轻其影响,确保作物的健康产量。机器学习算法已成为从经过训练的受影响作物图像数据集中准确识别各种植物病害并对其进行分类的强大工具。包括深度学习算法在内的这些算法在识别病害模式和植物病害早期症状方面取得了显著成功。除了早期检测,机器学习算法在植物病害的整体管理方面还有其他潜在优势,如植物的土壤和气候条件预测、害虫识别、近距离检测等。多年来,研究重点一直放在使用机器学习算法检测植物病害上。然而,研究界对机器学习算法在植物病害管理其他重要领域的应用程度却知之甚少。有鉴于此,我们对设计用于植物病害检测的机器学习算法和应用进行了横向比较综述,重点关注四(4)种具有重要经济价值的植物:苹果、木薯、棉花和马铃薯。我们对 2013 年至 2023 年间发表的文章进行了系统性综述,以探索多年来研究界的发展趋势。根据我们的纳入标准筛选了一些文章,包括介绍与所选植物相关的病害类别的单个预测准确性的文章,最后有 113 篇文章被认为是相关的。我们从这些文章中分析了利用机器学习识别选定植物病害的最新技术、挑战和未来前景。综述结果表明,深度学习和其他算法在检测植物病害方面表现出色。此外,我们还发现了一些关于植物病害管理的参考文献,内容涉及预防、诊断、控制和监测。有鉴于此,很少或根本没有研究如何预测受影响植物的恢复情况。因此,我们建议开发基于机器学习的技术,以涵盖预防、诊断、控制、监测和恢复。
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Cross-comparative review of Machine learning for plant disease detection: apple, cassava, cotton and potato plants

Plant disease detection has played a significant role in combating plant diseases that pose a threat to global agriculture and food security. Detecting these diseases early can help mitigate their impact and ensure healthy crop yields. Machine learning algorithms have emerged as powerful tools for accurately identifying and classifying a wide range of plant diseases from trained image datasets of affected crops. These algorithms, including deep learning algorithms, have shown remarkable success in recognizing disease patterns and early signs of plant diseases. Besides early detection, there are other potential benefits of machine learning algorithms in overall plant disease management, such as soil and climatic condition predictions for plants, pest identification, proximity detection, and many more. Over the years, research has focused on using machine-learning algorithms for plant disease detection. Nevertheless, little is known about the extent to which the research community has explored machine learning algorithms to cover other significant areas of plant disease management. In view of this, we present a cross-comparative review of machine learning algorithms and applications designed for plant disease detection with a specific focus on four (4) economically important plants: apple, cassava, cotton, and potato. We conducted a systematic review of articles published between 2013 and 2023 to explore trends in the research community over the years. After filtering a number of articles based on our inclusion criteria, including articles that present individual prediction accuracy for classes of disease associated with the selected plants, 113 articles were considered relevant. From these articles, we analyzed the state-of-the-art techniques, challenges, and future prospects of using machine learning for disease identification of the selected plants. Results from our review show that deep learning and other algorithms performed significantly well in detecting plant diseases. In addition, we found a few references to plant disease management covering prevention, diagnosis, control, and monitoring. In view of this, little or no work has explored the prediction of the recovery of affected plants. Hence, we propose opportunities for developing machine learning-based technologies to cover prevention, diagnosis, control, monitoring, and recovery.

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来源期刊
Artificial Intelligence in Agriculture
Artificial Intelligence in Agriculture Engineering-Engineering (miscellaneous)
CiteScore
21.60
自引率
0.00%
发文量
18
审稿时长
12 weeks
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