Saved in:
Bibliographic Details
Main Authors: Herrera-Poyato, David, Domínguez-Rull, Jacinto, Montes, Rosana, Hernánde, Inés, Barrio, Ignacio, Poblete-Echeverria, Carlos, Tardaguila, Javier, Herrera, Francisco, Herrera-Poyatos, Andrés
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.17119
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910619891924992
author Herrera-Poyato, David
Domínguez-Rull, Jacinto
Montes, Rosana
Hernánde, Inés
Barrio, Ignacio
Poblete-Echeverria, Carlos
Tardaguila, Javier
Herrera, Francisco
Herrera-Poyatos, Andrés
author_facet Herrera-Poyato, David
Domínguez-Rull, Jacinto
Montes, Rosana
Hernánde, Inés
Barrio, Ignacio
Poblete-Echeverria, Carlos
Tardaguila, Javier
Herrera, Francisco
Herrera-Poyatos, Andrés
contents Early detection of diseases in crops is essential to prevent harvest losses and improve the quality of the final product. In this context, the combination of machine learning and proximity sensors is emerging as a technique capable of achieving this detection efficiently and effectively. For example, this machine learning approach has been applied to potato crops -- to detect late blight (Phytophthora infestans) -- and grapevine crops -- to detect downy mildew. However, most of these AI models found in the specialised literature have been developed using leaf-by-leaf images taken in the lab, which does not represent field conditions and limits their applicability. In this study, we present the first machine learning model capable of detecting mild symptoms of late blight in potato crops through the analysis of high-resolution RGB images captured directly in the field, overcoming the limitations of other publications in the literature and presenting real-world applicability. Our proposal exploits the availability of high-resolution images via the concept of patching, and is based on deep convolutional neural networks with a focal loss function, which makes the model to focus on the complex patterns that arise in field conditions. Additionally, we present a data augmentation scheme that facilitates the training of these neural networks with few high-resolution images, which allows for development of models under the small data paradigm. Our model correctly detects all cases of late blight in the test dataset, demonstrating a high level of accuracy and effectiveness in identifying early symptoms. These promising results reinforce the potential use of machine learning for the early detection of diseases and pests in agriculture, enabling better treatment and reducing their impact on crops.
format Preprint
id arxiv_https___arxiv_org_abs_2409_17119
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Small data deep learning methodology for in-field disease detection
Herrera-Poyato, David
Domínguez-Rull, Jacinto
Montes, Rosana
Hernánde, Inés
Barrio, Ignacio
Poblete-Echeverria, Carlos
Tardaguila, Javier
Herrera, Francisco
Herrera-Poyatos, Andrés
Computer Vision and Pattern Recognition
Early detection of diseases in crops is essential to prevent harvest losses and improve the quality of the final product. In this context, the combination of machine learning and proximity sensors is emerging as a technique capable of achieving this detection efficiently and effectively. For example, this machine learning approach has been applied to potato crops -- to detect late blight (Phytophthora infestans) -- and grapevine crops -- to detect downy mildew. However, most of these AI models found in the specialised literature have been developed using leaf-by-leaf images taken in the lab, which does not represent field conditions and limits their applicability. In this study, we present the first machine learning model capable of detecting mild symptoms of late blight in potato crops through the analysis of high-resolution RGB images captured directly in the field, overcoming the limitations of other publications in the literature and presenting real-world applicability. Our proposal exploits the availability of high-resolution images via the concept of patching, and is based on deep convolutional neural networks with a focal loss function, which makes the model to focus on the complex patterns that arise in field conditions. Additionally, we present a data augmentation scheme that facilitates the training of these neural networks with few high-resolution images, which allows for development of models under the small data paradigm. Our model correctly detects all cases of late blight in the test dataset, demonstrating a high level of accuracy and effectiveness in identifying early symptoms. These promising results reinforce the potential use of machine learning for the early detection of diseases and pests in agriculture, enabling better treatment and reducing their impact on crops.
title Small data deep learning methodology for in-field disease detection
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2409.17119