Smartphone-Based Citizen Science Tool for Plant Disease and Insect Pest Detection Using Artificial Intelligence

Panagiotis Christakakis, Garyfallia Papadopoulou, Georgios Mikos, Nikolaos Kalogiannidis, D. Ioannidis, D. Tzovaras, E. Pechlivani
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Abstract

In recent years, the integration of smartphone technology with novel sensing technologies, Artificial Intelligence (AI), and Deep Learning (DL) algorithms has revolutionized crop pest and disease surveillance. Efficient and accurate diagnosis is crucial to mitigate substantial economic losses in agriculture caused by diseases and pests. An innovative Apple® and Android™ mobile application for citizen science has been developed, to enable real-time detection and identification of plant leaf diseases and pests, minimizing their impact on horticulture, viticulture, and olive cultivation. Leveraging DL algorithms, this application facilitates efficient data collection on crop pests and diseases, supporting crop yield protection and cost reduction in alignment with the Green Deal goal for 2030 by reducing pesticide use. The proposed citizen science tool involves all Farm to Fork stakeholders and farm citizens in minimizing damage to plant health by insect and fungal diseases. It utilizes comprehensive datasets, including images of various diseases and insects, within a robust Decision Support System (DSS) where DL models operate. The DSS connects directly with users, allowing them to upload crop pest data via the mobile application, providing data-driven support and information. The application stands out for its scalability and interoperability, enabling the continuous integration of new data to enhance its capabilities. It supports AI-based imaging analysis of quarantine pests, invasive alien species, and emerging and native pests, thereby aiding post-border surveillance programs. The mobile application, developed using a Python-based REST API, PostgreSQL, and Keycloak, has been field-tested, demonstrating its effectiveness in real-world agriculture scenarios, such as detecting Tuta absoluta (Meyrick) infestation in tomato cultivations. The outcomes of this study in T. absoluta detection serve as a showcase scenario for the proposed citizen science tool’s applicability and usability, demonstrating a 70.2% accuracy (mAP50) utilizing advanced DL models. Notably, during field testing, the model achieved detection confidence levels of up to 87%, enhancing pest management practices.
基于智能手机的公民科学工具,利用人工智能检测植物病虫害
近年来,智能手机技术与新型传感技术、人工智能(AI)和深度学习(DL)算法的融合,为作物病虫害监测带来了革命性的变化。高效准确的诊断对于减少病虫害给农业造成的巨大经济损失至关重要。我们为公民科学开发了一款创新的 Apple® 和 Android™ 移动应用程序,能够实时检测和识别植物叶片病虫害,最大限度地减少其对园艺、葡萄栽培和橄榄种植的影响。利用 DL 算法,该应用程序有助于高效收集作物病虫害数据,通过减少杀虫剂的使用来支持作物产量保护和降低成本,从而与 2030 年绿色交易目标保持一致。拟议的公民科学工具让 "从农场到餐桌 "的所有利益相关者和农场公民参与进来,最大限度地减少昆虫和真菌疾病对植物健康的损害。该工具在一个强大的决策支持系统(DSS)中利用综合数据集,其中包括各种病虫害的图像,DL 模型在该系统中运行。DSS 与用户直接连接,允许用户通过移动应用程序上传作物病虫害数据,提供数据驱动的支持和信息。该应用程序因其可扩展性和互操作性而脱颖而出,能够不断整合新数据以增强其功能。它支持对检疫性有害生物、外来入侵物种、新出现有害生物和本地有害生物进行基于人工智能的成像分析,从而为边境后监测计划提供帮助。该移动应用程序是使用基于 Python- 的 REST API、PostgreSQL 和 Keycloak 开发的,已经过实地测试,证明了其在实际农业场景中的有效性,例如检测番茄种植中的 Tuta absoluta (Meyrick) 侵害。该研究在西红柿虫害检测方面取得的成果展示了拟议的公民科学工具的适用性和可用性,利用先进的 DL 模型证明了 70.2% 的准确率(mAP50)。值得注意的是,在实地测试中,该模型的检测置信度高达 87%,从而加强了害虫管理实践。
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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