Applying Multiple Deep Models to Predict Plant Pests in Advanced Agriculture

Authors

  • Van-Vinh Nguyen Information Technology Department, Vietnam
  • Van-Dung Hoang Ho Chi Minh City University of Technology and Education, Vietnam

Corressponding author's email:

dunghv@hcmute.edu.vn

DOI:

https://doi.org/10.54644/jte.72A.2022.1274

Keywords:

Deep learning, Machine learning, Plant pests, Diseases prediction, Smart agriculture

Abstract

Nowadays, advanced sciences and technologies have been wide applied to smart agriculture fields. There are many challenges to agricultural companies, and scientists. So that it is important task to investigate a solution to detect early of plant pests and diseases for appropriately treating to product green agriculture products with least environmental impacts. This paper presents a proposed approach for applying artificial intelligence, deep learning specifically, to classify some plant pests and diseases. We have investigated a number of deep architectures of machine learning for effective solution for pests prediction through agriculture images. Some deep neural models are studied to apply for feature extraction task. Particularly, we surveyed and experimented based on some well-known architectures such as ResNet, EfficientNet, MobileNet, NASNet. In the classified part, we proposed the use of fully connected neural network. To evaluation and analyze the performance effectiveness of the proposed approach, we collected plant image pests and diseases in agriculture circumstance. Dataset consists of 3,391 samples within 6 categories of plant pests and diseases. Generally, there is also imbalance problem of the plant pest samples in some categories. Therefore, we also applied data augmentation solutions to improve the accuracy of the prediction system. Experimental results show that the pest prediction approach based on deep learning techniques reaches high accuracy. Among of them the feature extraction backbone based on ResNet101 conducts the highest results with the ratios of accuracy, precision, recall, specificity and F1 are 99,25%, 97,84%, 97,83%, 99,53% and 97,82%, respectively.

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Author Biographies

Van-Vinh Nguyen, Information Technology Department, Vietnam

VAN-VINH NGUYEN received a bachelor's degree in Information Technology from Posts and Telecommunications Institute of Technology, Viet Nam, in 2011. Currently, he has been working at the Official Gazette – Informatics Center, the People's Committee Office of An Giang province

Van-Dung Hoang, Ho Chi Minh City University of Technology and Education, Vietnam

VAN-DUNG HOANG received the Ph.D. degree from the University of Ulsan, South Korea, in 2014. He was associated  and joined as a visitting researcher with the Intelligence Systems Laboratory, University of Ulsan , 2015. He joined the  Robotics Laboratory on Artificial Intelligence, Telecom SudParis as a postdoctoral fellow, 2016.  He has been serving as an associate professor in computer science, Faculty of Information Technology, Ho Chi Minh City University of Technology and Education, Vietnam. He has published numerous research articles in ISI, Scopus indexed, and high-impact factor journals. He has been actively participating as a member of the societies as IEEE, IEEE RAS, ICROS. His research interests include a wide area, which focuses on pattern recognition, machine learning, medical image processing, computer vision application, visionbased robotics and ambient intelligence.

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Published

28-10-2022

How to Cite

[1]
V. V. Nguyen and V. D. Hoang, “Applying Multiple Deep Models to Predict Plant Pests in Advanced Agriculture”, JTE, vol. 17, no. 5, pp. 63–72, Oct. 2022.

Issue

Vol. 17 No. 5 (2022)

Section

Research Article

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This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

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