Classification model for chlorophyll content using CNN and aerial images

Classification model for chlorophyll content using CNN and aerial images

•Spectral information distribution impacts deep learning model performance.•Chlorophyll content model using classification and transfer learning approach.•Classify chlorophyll content under biotic stress conditions like pests. Chlorophyll content is usually used as a quantitative measurement of plan...

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Bibliographic Details
Published in:Computers and electronics in agriculture Vol. 221; p. 109006
Main Authors: Wagimin, Mohd Nazuan, Ismail, Mohammad Hafiz bin, Fauzi, Shukor Sanim Mohd, Seng, Chuah Tse, Latif, Zulkiflee Abd, Muharam, Farrah Melissa, Zaki, Nurul Ain Mohd
Format: Journal Article
Language:English
Published: Elsevier B.V 01-06-2024
Subjects:
Classification model
CNN
Precision agriculture
Transfer learning
UAV
Precision agriculture
CNN
Classification model
UAV
Transfer learning
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Summary:•Spectral information distribution impacts deep learning model performance.•Chlorophyll content model using classification and transfer learning approach.•Classify chlorophyll content under biotic stress conditions like pests. Chlorophyll content is usually used as a quantitative measurement of plant health. The chlorophyll content is also a continuous number of data type, leading to a regression approach when developing the deep learning model. The regression model will predict the chlorophyll content in number format, which requires experts to analyse the outcome. Nevertheless, the analysis of the outcome could possibly lead to human error in diagnosing the plant’s health condition. Therefore, this study proposed a classification approach in developing a deep learning model to analyse the plant’s health condition without human intervention. The classification approach requires a discrete group for dependent variables instead of continuous numbers. When forming the chlorophyll content index groups in this study, which are low, optimum and high levels, two research studies were combined to form the groups, which were (1) the product of the standard range of nitrogen value in mango plant and (2) the correlation analysis between nitrogen value and chlorophyll content index. The classification model in this study used transfer learning algorithms, which were InceptionV3, DenseNet121 and ResNet50, with the canopy-scale level of mango plant RGB images with complex leaf structures in an uncontrolled and open area. Based on the findings, the classification model could classify the chlorophyll content index levels on both mango plant images, which were infected and not infected with black sooty mould. The finding also shows that a clearer distribution pattern of spectral information extracted from the mango plant images can influence the performance result of the classification model. Besides that, the starting point of the Digitization Footprint for this study site across the development stages of the classification model was 308.5756 MB/ha. Finally, the overall accuracy performances for the classification models that used the transfer learning algorithms, which were InceptionV3, DenseNet121, and ResNet50, and trained using the images of the mango plant infected with pest were 96.49 %, 92.98 %, and 89.47 %, respectively, and for using the images of the mango plant not infected with pest were 88.10 %, 78.57 %, and 69.05 %, respectively.
ISSN:0168-1699
1872-7107
DOI:10.1016/j.compag.2024.109006