Using EfficientNet and transfer learning for image-based diagnosis of nutrient deficiencies

•We performed nutrient deficiency identification by using deep learning techniques.•We evaluated different recent architectures and transfer learning strategies.•We used two different datasets for checking the generalization ability.•We used the Grad-CAM++ technique for validating the learning outpu...

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Bibliographic Details
Published inComputers and electronics in agriculture Vol. 196; p. 106868
Main Authors Espejo-Garcia, Borja, Malounas, Ioannis, Mylonas, Nikos, Kasimati, Aikaterini, Fountas, Spyros
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 01.05.2022
Elsevier BV
Subjects
Artificial neural networks
Color imagery
Datasets
Deep learning
Diagnosis
EfficientNet
Image classification
Iron
Machine learning
Magnesium
Manganese
Nutrient deficiency
Object recognition
Precision agriculture
Sugar beets
Transfer learning
Deep learning
Precision agriculture
EfficientNet
Nutrient deficiency
Transfer learning
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Summary:•We performed nutrient deficiency identification by using deep learning techniques.•We evaluated different recent architectures and transfer learning strategies.•We used two different datasets for checking the generalization ability.•We used the Grad-CAM++ technique for validating the learning output.•We have made publicly available a new dataset containing nutrient deficiencies in orange trees. Early diagnosis of nutrient deficiencies can play a major role in avoiding significant agricultural losses and increasing the final yield while preserving the environment through efficient fertilizer usage. In this work, we study how well nutrient deficiency symptoms can be recognized in RGB images by using deep neural networks and transfer learning. Two different datasets, presenting real-world conditions, were used for this purpose. The first one was the Deep Nutrient Deficiency for Sugar Beet (DND-SB) dataset, which contains 5648 images of sugar beets presenting nitrogen (N), phosphorous (P), and potassium (K) deficiencies, the omission of liming (Ca) and full fertilization. The second one, collected on the field for this research and currently publicly available, was a dataset combining different orange tree images with iron (Fe), potasssium (K), magnesium (Mg), and manganese (Mn) deficiencies. Image classification via fine-tuning with EfficientNetB4, whose original weights came from a noisy student training on ImageNet, obtained the best performances on both datasets with 98.65% and 98.52% Top-1 accuracies. Additionally, the Grad-CAM++ analysis showed that the models were performing an accurate analysis of the most relevant part inside the images. Finally, the use of agricultural transfer learning did not report improvement in the performances.
ISSN:0168-1699
1872-7107
DOI:10.1016/j.compag.2022.106868