Plant Health Prediction and Monitoring Based on convolution Neural Network in North-East India
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Abstract
Agriculture is the main backbone of any society. In this modern era as the population continuously increases, resources for farming are also decreasing. If the health condition of the plant’s determined at a regular interval, farmers can take action timely to improve the plant’s health condition. Plant monitoring and plant health status at regular intervals may lead to better growth of foods. But the regular physical visit to the crop field to monitor plants and plant health is a critical task for a large crop field. To overcome this situation, we need to shift from a traditional cropping system to smart agriculture. Now, these days, a smart agriculture-based approach can use the internet of things, machine learning, and deep learning to predict the health condition of plants. In this paper, the internet of things (IoT) based smart agriculture system has been presented along with machine learning, deep learning, and transfer learning to monitor and health prediction of plants. The IoT-based system has been used to monitor the plant’s surrounding parameters such as humidity, temperature, light intensity, and soil water moisture. The leaf images of plants have been used in deep learning (DL), machine learning (ML), and transfer learning (TL) to predict the health condition of plants. In this paper, the convolution neural network (CNN) based model has been proposed and it has been compared with the support vector machine (SVM), random forest (RF), VGG19, and mobilenet model. It has been concluded that the accuracy of the proposed CNN model is 81.5 %, which is the highest among SVM, RF, VGG19, and mobilenet..
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Bhagwan sahay meena; K. Hemachandran. An Experimental Approach for Understanding Internet of Things (IoT) for Corporate Model and Various Platforms. IJITEE, 2019, 8,7, 228-240.
Bhagwan Sahay Meena; K Hemachandran. Device-based Real-time Single User Indoor Localization Using Internet of Things. RACSC, 2021. doi: 10.2174/2666255814666210712114445.
Bhagwan Sahay Meena; Ramin Uddin Laskar; K Hemachandran. Indoor Localization-Based Office Automation System Using IoT Devices. Intelligent Computing in Engineering 2020, Springer, 1125, 199-210.
Bhagwan Sahay Meena; Sujoy Deb; K Hemachandran. Impact of heterogeneous IoT devices for indoor localization using RSSI. Intelligent Computing in Engineering, 2020, Springer, 1125, 187-198.
Bhagwan sahay meena. Device based multi-user tracking system using internet of things, IJRITCC, 2022, (Article in press).
G Geetha; S Samundeswari; G saranya; K Meenakshi; M Nithya. Plant Leaf Disease Classification and Detection System Using Machine Learning. Journal of Physics: Conference Series, 2020, 1712.
Muhammad Chowdhury; Tawsifur Rahman; Amith Khadkar; Mohammad Arselene Ayari; AftabUlmahkhan; Muhammad Salman Khan; Nasser Al-Emadi; Mamum Bin Reaz; MohammadTariqul Islam; Sawar Hamid MdAli. Automatic and Reliable Leaf Disease Detection Using Deep Learning technique. AgriEngineering 2021, 3, 294–312.
Monirul Islam Pavel; Syed Mohammad Kamruzzaman; SadmanSakibHasan; SaifurRahmanSabuj. An IoT Based Plant Health Monitoring System Implementing Image Processing. IEEE 4th International Conference on Computer and Communication Systems, singapor, 02 sep. 2019.
Sameer Patel; Mittal B.Jain; Sarvesh Pai; Sagar Korde. Smart agriculture using IoT and Machine Learning. IRJET 2021, 08 (04), 4533-4536.
Josh Doshi; Tirthkumar Patel; Santosh kumar Bharti. Smart Farming using IoT, a solution for optimally monitoring farming conditions. Procedia Computer Science, 160,746-751, 2019.
Maryam Ouhami; Adel Hafiane; Youssef Es-Saady; Mohamed El Hajji; Raphael Canals. Computer Vision, IoT and Data Fusion for Crop Disease Detection Using Machine Learning: A Survey and Ongoing Research. Remote Sens. 2021 13(13), 2486.
Disha Garg; Manshaf Alam. Deep Learning and IoT for Agriculture Applications. Book chapter - Internet of things (IoT), S.M.A.R.T, Springer, 273-284,2020. DOI:10.1007/978-3-030-37468-6_14.
R Juhi Reshma; Anitha S Pillai. Impact of Machine Learning and internet of things in Agriculture, The state of the art. International Conference on Soft Computing and Pattern Recognition, 2018. DOI:10.1007/978-3-319-60618-7_59.
Amal Dewangan. Application of IoT And Machine Learning in Agriculture. IJERT 2020, 09 (07).
Mario Bkassiny; Sudharman K. Jayaweera. A Survey on Machine-Learning Techniques in Cognitive Radios. IEEE communications surveys and tutorials 2013, 15 ,3.
Keiron O’Shea; Ryan Nash. An Introduction to Convolutional Neural Networks, 2015.
Muhammad Mateen; Junhao Wen; Nasrullah; Sun Song; Zhouping Huang. Fundus Image Classification Using VGG-19 Architecture with PCA and SVD. Symmetry 2018, 11, 1.
Wei Wang; Yutao Li; Ting Zou; Xin Wang; Jieyu You; Yanhong Luo. A novel image classification via Dense-MobileNet model. Mobile Information Systems, 2020. doi.org/10.1155/2020/7602384.
Ricardo Llugsi; Samira El Yacoubi; Allyx Fontaine; Pablo Lupera. Comparison between Adam, AdaMax and AdamW optimizers to implement a Weather Forecast based on Neural Networks for the Andean city of Quito. IEEE fifth ecudor technical chapters meeting, 13 November ,2021, Cuenca, Ecudor. 10.1109/ETCM53643.2021.9590681.
Xue Ying. An overview of over fitting and its solution. Journal of Physics: Conference series 2018,2, 1168.