Estimation of flea beetle damage in the field using a multistage deep learning-based solution

IF 8.2 Q1 AGRICULTURE, MULTIDISCIPLINARY

Artificial Intelligence in Agriculture Pub Date : 2024-06-06 DOI:10.1016/j.aiia.2024.06.001

Arantza Bereciartua-Pérez , María Monzón , Daniel Múgica , Greta De Both , Jeroen Baert , Brittany Hedges , Nicole Fox , Jone Echazarra , Ramón Navarra-Mestre

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Abstract

Estimation of damage in plants is a key issue for crop protection. Currently, experts in the field manually assess the plots. This is a time-consuming task that can be automated thanks to the latest technology in computer vision (CV). The use of image-based systems and recently deep learning-based systems have provided good results in several agricultural applications. These image-based applications outperform expert evaluation in controlled environments, and now they are being progressively included in non-controlled field applications.

A novel solution based on deep learning techniques in combination with image processing methods is proposed to tackle the estimate of plant damage in the field. The proposed solution is a two-stage algorithm. In a first stage, the single plants in the plots are detected by an object detection YOLO based model. Then a regression model is applied to estimate the damage of each individual plant. The solution has been developed and validated in oilseed rape plants to estimate the damage caused by flea beetle.

The crop detection model achieves a mean precision average of 91% with a [email protected] of 0.99 and a [email protected] of 0.91 for oilseed rape specifically. The regression model to estimate up to 60% of damage degree in single plants achieves a MAE of 7.11, and R2 of 0.46 in comparison with manual evaluations done plant by plant by experts. Models are deployed in a docker, and with a REST API communication protocol they can be inferred directly for images acquired in the field from a mobile device.

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使用基于多级深度学习的解决方案估算田间跳甲危害情况

估算植物受损情况是作物保护的一个关键问题。目前，田间专家需要对地块进行人工评估。这是一项耗时的工作，但借助计算机视觉（CV）领域的最新技术，这项工作可以实现自动化。基于图像的系统以及最近基于深度学习的系统在一些农业应用中取得了良好的效果。这些基于图像的应用在受控环境中的表现优于专家评估，现在它们正逐渐被纳入非受控田间应用中。所提出的解决方案是一种两阶段算法。在第一阶段，通过基于对象检测 YOLO 的模型检测地块中的单株植物。然后应用回归模型来估算每棵单株植物的损害程度。作物检测模型的平均精确度达到 91%，[email protected] 为 0.99，油菜的[email protected] 为 0.91。回归模型可估算单株植物 60% 的损害程度，与专家逐株进行的人工评估相比，其 MAE 为 7.11，R2 为 0.46。模型部署在 docker 中，通过 REST API 通信协议，可以直接推断出移动设备在田间获取的图像。

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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