Perception of Groundnuts Leaf Disease by Neural Network with Progressive Re-Sizing
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Abstract
India is the world's second-largest groundnut producer after Brazil. An major crop of oilseeds is groundnuts. Because of this, the crop's quality and yield have declined, which has had a detrimental effect on the agricultural economy. This is partly because the crop is more susceptible to various diseases. It is required to create more precise and reliable automated approaches to address this problem and improve the identification of groundnut leaf diseases. This article proposes a deep learning-driven approach based on a progressive scaling technique for the accurate classification and identification of groundnut leaf diseases. The five main groundnut leaf diseases that are the subject of this study are leaf spot, armyworm effect, wilts, yellow leaf, and healthy leaf. The proposed model is trained using both progressive resizing and conventional techniques, and its performance is assessed using cross-entropy loss. A fresh dataset is meticulously curated in Gujarat state, India's Saurashtra region, for training and validation. Due to the dataset's uneven sample distribution across disease categories, an extended focus loss function was used to correct this class imbalance. In order to evaluate the performance of the suggested model, a number of performance metrics are utilized, including accuracy, sensitivity, F1-score, precision, and sensitivity. Notably, the suggested model has a 96.12% success rate, which signifies a considerable increase in the disease identification accuracy. It's important to note that the model incorporating progressive resizing beats the basic neural network-based model based on cross-entropy loss, highlighting the potency of the recommended approach.
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References
H. Park, J. S. Eun and S. H. Kim, Image-based disease diagnosing and predicting of the crops through the deep learning mechanism, In Information and Communication Technology Convergence (ICTC), IEEE 2017 International Conference on, pp. 129-131, 2017.
K. Elangovan and S. Nalini, Plant disease classification using image segmentation and SVM techniques, International Journal of Computational Intelligence Research, vol. 13(7), pp. 1821-1828, 2017.
A. Vibhute and S. K. Bodhe, Applications of Image Processing in Agriculture: A Survey, International Journal of Computer Applications, vol. 52, no. 2, pp. 34-40, 2012.
S. Militante, Fruit Grading of Garcinia Binucao (Batuan) using Image Processing, International Journal of Recent Technology and Engineering (IJRTE), vol. 8 issue 2, pp. 1829- 1832, 2019
Chen J, Yin H, Zhang D (2020) A self-adaptive classification method for plant disease detection using GMDH-Logistic model. Sustain Comput Inform Syst28:100415
Atila Ü et al (2021) Plant leaf disease classification using efficientnet deep learning model. Ecol Inform 61:10118
S.P. Mohanty, D.P. Hughes, and M. Salathé Using deep learning for image-based plant disease detection, in Frontiers in plant science 7, p. 1419,2016.
B. Benuwa, Y. Zhao Zhan, B. Ghansah, D. Wornyo, & F. Banaseka, A Review of Deep Machine Learning, International Journal of Engineering Research inAfrica, 24, pp 124-136, 2016, 10.4028/www.scientific.net/JERA.24.124.
Y. Su, F. Jurie. Improving Image Classification Using Semantic Attributes, International Journal of Computer Vision, Springer Verlag, 2012, 100 (1), pp.59-77. 10.1007/s11263-012-0529-4.
Y. LeChun, Y. Bengio and G. Hinton, Deep Learning, Nature, vol. 521, pp. 436-444, 2015. eprint https://doi.org/10.1038/nature14539
S. H. Lee, C. S. Chan, S. J. Mayo and P. Remagnino, How deep learning extracts and learns leaf features for the plant classification, Pattern Recognition, vol. 71, pp. 1-13, 2017.
K.P. Ferentinos, Deep learning models for plant disease detection and diagnosis, Computers and Electronics in Agriculture, vol. 145, pp. 311-318,2018
Zakieldeen Aboabuda Mohammed Alhassn Ali, Mona Yahya S. Alfefi. (2023). Applications of Integration and Differentiation in Real Life. International Journal of Intelligent Systems and Applications in Engineering, 11(4s), 611–615. Retrieved from https://ijisae.org/index.php/IJISAE/article/view/2738
H. Durmus, E. O. Gunes¸ and M. Kirci, Disease detection on the leaves of the tomato plants by using deep learning, In Agro-Geoinformatics, IEEE 6thInternational Conference on, pp. 1-5, 2017.
H. A. Atabay, Deep residual learning for tomato plant leaf disease identification, Journal of Theoretical & Applied Information Technology, vol. 95 no. 24 pp. 6800-6808, 2017.
D.P. Hughes, and M. Salathé, An open access repository of images on plant health to enable the development of mobile disease diagnostics, arXiv:1511.08060, 2015
V. Tumen, O. F. Soylemez and B. Ergen, Facial emotion recognition on a dataset using convolutional neural network, 2017 International Artificial Intelligence and Data Processing Symposium (IDAP), 2017.
Paul A et al (2020) A review on agricultural advancement based on computer vision and machine learning. Emerging technology in modelling and graphics. Springer, New York, pp 567–581
F. N. Iandola, S. Han, M. W. Moskewicz, K. Ashraf, W. J. Dally, and K. Keutzer, Squeezenet: AlexNet- Level Accuracy with 50x Fewer Parameters and <0.5MB Model Size, eprint arXiv:1602.07360v4, pp. 1- 13, 2016
A comparative study of fine-tuning deep learning models for plant disease identification- Edna Chebet Tooa, Li Yujiana , Sam Njukia , Liu Yingchun
Deep Convolutional Neural Network based Detection System for Real-time Corn Plant Disease Recognition -Sumita Mishraa , Rishabh Sachana , Diksha Rajpala
Deep learning models for plant disease detection and diagnosis-Konstantinos P. Ferentinos 24
Using deep transfer learning for image-based plant disease identification -Junde Chena , Jinxiu Chena , Defu Zhanga, , Yuandong Sunb , Y.A. Nanehkarana
Le VNT et al (2020) A novel method for detecting morphologically similar crops and weeds based on the combination of contour masks and filtered Local Binary Pattern operators. GigaScience 9(3):giaa017
Ahmad W, Shah S, Irtaza A (2020) Plants disease phenotyping using quinary patterns as texture descriptor. KSII Trans Internet Inf Syst 14(8):3312–3327
Sun Y et al (2019) SLIC_SVM based leaf diseases saliency map extraction of tea plant. Comput Electron Agric 157:102–109
Dr. Avinash Pawar. (2020). Development and Verification of Material Plasma Exposure Concepts. International Journal of New Practices in Management and Engineering, 9(03), 11 - 14. https://doi.org/10.17762/ijnpme.v9i03.90
Albahli S et al (2021) Recognition and Detection of Diabetic Retinopathy Using Densenet-65 Based Faster-RCNN. Comput Mater Contin 67:1333–1351
Le VNT et al (2020) A novel method for detecting morphologically similar crops and weeds based on the combination of contour masks and filtered Local Binary Pattern operators. GigaScience 9(3):giaa017
Ahmad W, Shah S, Irtaza A (2020) Plants disease phenotyping using quinary patterns as texture descriptor. KSII Trans Internet Inf Syst 14(8):3312–3327
Sun Y et al (2019) SLIC_SVM based leaf diseases saliency map extraction of tea plant. Comput Electron Agric 157:102–109
Oo YM, Htun NC (2018) Plant leaf disease detection and classification using image processing. Int J Res Eng 5(9):516–523