FOREX Press I. J. of Electrical & Electronics Research
Support Open Access

Research Article |

Development of Smart Agriculture to detect the Arabica Coffee Leaf Disease using IAFSA based MSAB with Channel and Spatial Attention Network

Author(s): Dr. R Saravanakumar*, Dr. Puneet Matapurkar, Dr. G. Shivakanth, Dr Vinay Kumar Nassa, Dr. Santosh Kumar and Dr. S. Poonguzhali

Publisher : FOREX Publication

Published : 28 March 2024

e-ISSN : 2347-470X

Page(s) : 06-11




Dr. R Saravanakumar*, Associate Professor, Department of ECE Saveetha School of Engineering, Saveetha Institute of Medical and Technical Sciences, Saveetha University, Chennai, India; Email: saravanakumarr.sse@saveetha.com

Dr. Puneet Matapurkar, Assistant Professor, Department of Mathematical Sciences and Computer Applications, Bundelkhand University, Jhansi (U.P.), Pin code 284128; Email: pmatapurkar.mca@gmail.com

Dr. G. Shivakanth, Associate Professor, Dept. of CSE, Koneru Lakshmaiah Education Foundation, Vaddeswaram, Guntur, Andhra Pradesh, Bharat; Email: shvkanth0@gmail.com

Dr Vinay Kumar Nassa, Professor Department of Information Communication Technology (ICT), Tecnia Institute of Advanced Studies (Delhi), Affiliated with Guru Gobind Singh Indraprastha University; Email: vn.nassa@gmail.com

Dr. Santosh Kumar, Professor, Department of Computer Science, ERA University, Lucknow, Uttar Pradesh; Email: sanb2lpcps@gmail.com

Dr. S. Poonguzhali, Assistant Professor, VIT School of Agricultural Innovations and Advanced Learning, Vellore Institute of Technology, Vellore, Tamil Nadu, India; Email: poonguzhalimanian@gmail.com

    [1] Kumar, M., Gupta, P., & Madhav, P. (2020, June). Disease detection in coffee plants using convolutional neural network. In 2020 5th International Conference on Communication and Electronics Systems (ICCES) (pp. 755-760). IEEE.
    [2] De Vita, F., Nocera, G., Bruneo, D., Tomaselli, V., Giacalone, D., & Das, S. K. (2020, September). Quantitative analysis of deep leaf: a plant disease detector on the smart edge. In 2020 IEEE International Conference on Smart Computing (SMARTCOMP) (pp. 49-56). IEEE.
    [3] Dutta, L., & Rana, A. K. (2021, October). Disease Detection Using Transfer Learning in Coffee Plants. In 2021 2nd Global Conference for Advancement in Technology (GCAT) (pp. 1-4). IEEE.
    [4] Sunil, C. K., Jaidhar, C. D., & Patil, N. (2021). Cardamom plant disease detection approach using EfficientNetV2. IEEE Access, 10, 789-804.
    [5] Pinto, L. A., Mary, L., & Dass, S. (2021, August). The Real-Time Mobile Application for Identification of Diseases in Coffee Leaves using the CNN Model. In 2021 Second International Conference on Electronics and Sustainable Communication Systems (ICESC) (pp. 1694-1700). IEEE.
    [6] Rahul, M. S. P., & Rajesh, M. (2020, August). Image processing based Automatic Plant Disease Detection and Stem Cutting Robot. In 2020 Third International Conference on Smart Systems and Inventive Technology (ICSSIT) (pp. 889-894). IEEE.
    [7] Sunil, C. K., Jaidhar, C. D., & Patil, N. (2022). Binary class and multi-class plant disease detection using ensemble deep learning-based approach. International Journal of Sustainable Agricultural Management and Informatics, 8(4), 385-407.
    [8] Waldamichael, F. G., Debelee, T. G., & Ayano, Y. M. (2022). Coffee disease detection using a robust HSV color‐based segmentation and transfer learning for use on smartphones. International Journal of Intelligent Systems, 37(8), 4967-4993.
    [9] Kaur, S., Rakhra, M., Singh, D., Singh, A., & Aggarwal, S. (2022, October). Disease Detection in Cactus (Beles) via the Use of Machine Learning: A Proposed Technique. In 2022 2nd International Conference on Technological Advancements in Computational Sciences (ICTACS) (pp. 772-778). IEEE.
    [10] Yebasse, M., Shimelis, B., Warku, H., Ko, J., & Cheoi, K. J. (2021). Coffee disease visualization and classification. Plants, 10(6), 1257.
    [11] Ahmad, A., Saraswat, D., & El Gamal, A. (2023). A survey on using deep learning techniques for plant disease diagnosis and recommendations for development of appropriate tools. Smart Agricultural Technology, 3, 100083.
    [12] Abd Algani, Y. M., Caro, O. J. M., Bravo, L. M. R., Kaur, C., Al Ansari, M. S., & Bala, B. K. (2023). Leaf disease identification and classification using optimized deep learning. Measurement: Sensors, 25, 100643.
    [13] Kouadio, L., El Jarroudi, M., Belabess, Z., Laasli, S. E., Roni, M. Z. K., Amine, I. D. I., ... & Lahlali, R. (2023). A Review on UAV-Based Applications for Plant Disease Detection and Monitoring. Remote Sensing, 15(17), 4273.
    [14] Delnevo, G., Girau, R., Ceccarini, C., & Prandi, C. (2021). A deep learning and social iot approach for plants disease prediction toward a sustainable agriculture. IEEE Internet of Things Journal, 9(10), 7243-7250.
    [15] Li, L., Zhang, S., & Wang, B. (2021). Plant disease detection and classification by deep learning—a review. IEEE Access, 9, 56683-56698.
    [16] Ramamurthy, K., Thekkath, R. D., Batra, S., & Chattopadhyay, S. (2023). A novel deep learning architecture for disease classification in Arabica coffee plants. Concurrency and Computation: Practice and Experience, 35(8), e7625.
    [17] Milke, E. B., Gebiremariam, M. T., & Salau, A. O. (2023). Development of a coffee wilt disease identification model using deep learning. Informatics in Medicine Unlocked, 101344.
    [18] Aufar, Y., Abdillah, M. H., & Romadoni, J. (2023). Web-based CNN Application for Arabica Coffee Leaf Disease Prediction in Smart Agriculture. Jurnal Resti (Rekayasa Sistem Dan Teknologi Informasi), 7(1), 71-79.
    [19] Karthik, R., Alfred, J. J., & Kennedy, J. J. (2023). Inception-based global context attention network for the classification of coffee leaf diseases. Ecological Informatics, 77, 102213.
    [20] Raghavendra, B. K. (2023). An Efficient Approach for Coffee Leaf Disease Classification and Severity Prediction. International Journal of Intelligent Engineering & Systems, 16(5).
    [21] J. Jepkoech, D. M. Mugo, B. K. Kenduiywo, and E. C. Too, “Arabica coffee leaf images dataset for coffee leaf disease detection and classification,” Data Br., vol. 36, p. 107142, 2021, doi: 10.1016/j.dib.2021.107142.
    [22] He, K.; Zhang, X.; Ren, S.; Sun, J. Deep Residual Learning for Image Recognition. arXiv 2015, arXiv:1512.03385.
    [23] Geng, J.; Wang, H.; Fan, J.; Ma, X. SAR Image Classification via Deep Recurrent Encoding Neural Networks. IEEE Trans. Geosci. Remote Sens. 2021, 56, 2255–2269.
    [24] Pourpanah, F.; Wang, R.; Lim, C.P.; Wang, X.Z.; Yazdani, D. A review of artificial fish swarm algorithms: Recent advances and applications. Artif. Intell. Rev. 2023, 56, 1867–1903.

Dr. R Saravanakumar, Dr. Puneet Matapurkar, Dr. G. Shivakanth, Dr Vinay Kumar Nassa, Dr. Santosh Kumar and Dr. S. Poonguzhali (2024), Development of Smart Agriculture to detect the Arabica Coffee Leaf Disease using IAFSA based MSAB with Channel and Spatial Attention Network. IJEER 12(bdf), 06-11. DOI: 10.37391/ijeer.12bdf02.