A Framework for Agricultural Pest and Disease Monitoring Based on Internet-of-Things and Unmanned Aerial Vehicles

With the development of information technology, Internet-of-Things (IoT) and low-altitude remote-sensing technology represented by Unmanned Aerial Vehicles (UAVs) are widely used in environmental monitoring fields. In agricultural modernization, IoT and UAV can monitor the incidence of crop diseases and pests from the ground micro and air macro perspectives, respectively. IoT technology can collect real-time weather parameters of the crop growth by means of numerous inexpensive sensor nodes. While depending on spectral camera technology, UAVs can capture the images of farmland, and these images can be utilize for analyzing the occurrence of pests and diseases of crops. In this work, we attempt to design an agriculture framework for providing profound insights into the specific relationship between the occurrence of pests/diseases and weather parameters. Firstly, considering that most farms are usually located in remote areas and far away from infrastructure, making it hard to deploy agricultural IoT devices due to limited energy supplement, a sun tracker device is designed to adjust the angle automatically between the solar panel and the sunlight for improving the energy-harvesting rate. Secondly, for resolving the problem of short flight time of UAV, a flight mode is introduced to ensure the maximum utilization of wind force and prolong the fight time. Thirdly, the images captured by UAV are transmitted to the cloud data center for analyzing the degree of damage of pests and diseases based on spectrum analysis technology. Finally, the agriculture framework is deployed in the Yangtze River Zone of China and the results demonstrate that wheat is susceptible to disease when the temperature is between 14 °C and 16 °C, and high rainfall decreases the spread of wheat powdery mildew.

[1]  Yunfei Liu,et al.  Anycast Routing Protocol for Forest Monitoring in Rechargeable Wireless Sensor Networks , 2013, Int. J. Distributed Sens. Networks.

[2]  Tian He,et al.  RowBee: A Routing Protocol Based on Cross-Technology Communication for Energy-Harvesting Wireless Sensor Networks , 2019, IEEE Access.

[3]  Weronika Swiergiel,et al.  Development of sustainable plant protection programs through multi-actor Co-innovation: An 8-year case study in Swedish apple production , 2019, Journal of Cleaner Production.

[4]  Xia Sun,et al.  State-of-the-Art Internet of Things in Protected Agriculture , 2019, Sensors.

[5]  Dmitry Bratanov,et al.  A Novel Methodology for Improving Plant Pest Surveillance in Vineyards and Crops Using UAV-Based Hyperspectral and Spatial Data , 2018, Sensors.

[6]  M. Donatelli,et al.  Modelling the impacts of pests and diseases on agricultural systems , 2017, Agricultural systems.

[7]  Andreas Kamilaris,et al.  A review on the practice of big data analysis in agriculture , 2017, Comput. Electron. Agric..

[8]  Istas Pratomo,et al.  Expert system for diagnosis pests and diseases of the rice plant using forward chaining and certainty factor method , 2017, 2017 International Seminar on Intelligent Technology and Its Applications (ISITIA).

[9]  Kun Shi,et al.  A Research for the Influence of Tilt Angles of the Solar Panel on Photovoltaic Power Generation , 2018, 2018 International Conference on Smart Grid and Clean Energy Technologies (ICSGCE).

[10]  Sim Heng Ong,et al.  A Small UAV Based Multi-Temporal Image Registration for Dynamic Agricultural Terrace Monitoring , 2017, Remote. Sens..

[11]  Konstantinos G. Arvanitis,et al.  SensoTube: A Scalable Hardware Design Architecture for Wireless Sensors and Actuators Networks Nodes in the Agricultural Domain , 2016, Sensors.

[12]  Jo Anne Crouch,et al.  Downy Mildew: A Serious Disease Threat to Rose Health Worldwide. , 2018, Plant disease.

[13]  Liang Nan,et al.  Application of UAV low-altitude remote sensing , 2017 .

[14]  Kozo Mayumi,et al.  Toward an integrated assessment of the performance of photovoltaic power stations for electricity generation , 2017 .

[15]  K. Lamour,et al.  Advances in Research on Phytophthora capsici on Vegetable Crops in The United States. , 2012, Plant disease.

[16]  H. Muhammed,et al.  Measuring crop status using multivariate analysis of hyperspectral field reflectance with application to disease severity and plant density , 2007, Precision Agriculture.

[17]  David Reiser,et al.  3-D Imaging Systems for Agricultural Applications—A Review , 2016, Sensors.

[18]  Guoqiang Zhong,et al.  A deep-learning model for the amplitude inversion of internal waves based on optical remote-sensing images , 2018 .

[19]  Aiguo Song,et al.  Improved hop-based localisation algorithm for irregular networks , 2019, IET Commun..

[20]  Gemma Hornero,et al.  Design of a low-cost Wireless Sensor Network with UAV mobile node for agricultural applications , 2015, Comput. Electron. Agric..

[21]  Yonghui Zhang,et al.  Maritime wireless broadband communication system based on TVWS , 2015, ICM 2015.

[22]  Mayabini Jena,et al.  Toxicological effect of underutilized plant, Cleistanthus collinus leaf extracts against two major stored grain pests, the rice weevil, Sitophilus oryzae and red flour beetle, Tribolium castaneum. , 2018, Ecotoxicology and environmental safety.

[23]  Søren Blaaberg,et al.  HySpex ODIN-1024: a new high-resolution airborne HSI system , 2014, Defense + Security Symposium.

[24]  Chee Yen Leow,et al.  An Overview of Internet of Things (IoT) and Data Analytics in Agriculture: Benefits and Challenges , 2018, IEEE Internet of Things Journal.

[25]  Jianhua Wang,et al.  Measuring Rice Farmer’s Pesticide Overuse Practice and the Determinants: A Statistical Analysis Based on Data Collected in Jiangsu and Anhui Provinces of China , 2018 .

[26]  Shuo Zhang,et al.  Wildfire Detection Using Sound Spectrum Analysis Based on the Internet of Things , 2019, Sensors.

[27]  Heike E. Meissner,et al.  PestLens: an early‐warning system supporting U.S. safeguarding against exotic plant pests , 2015 .

[28]  Wilhelm Rademacher,et al.  Plant Growth Regulators: Backgrounds and Uses in Plant Production , 2015, Journal of Plant Growth Regulation.

[29]  Fuquan Zhang,et al.  Maximum Data Generation Rate Routing Protocol based on Data Flow Controlling Technology for Rechargeable Wireless Sensor Networks , 2019, Computers, Materials & Continua.

[30]  Gaurav Singhal,et al.  A comparision between satellite based and drone based remote sensing technology to achieve sustainable development: a review , 2017 .

[31]  Gary E. Vallad,et al.  Crop protection: Pest and Disease Management , 2018 .

[32]  Minzan Li,et al.  Predicting chlorophyll content of greenhouse tomato with ground-based remote sensing , 2010, Asia-Pacific Remote Sensing.

[33]  Wenjiang Huang,et al.  New Spectral Index for Detecting Wheat Yellow Rust Using Sentinel-2 Multispectral Imagery , 2018, Sensors.

[34]  Xi Cheng,et al.  Agricultural Pests Tracking and Identification in Video Surveillance Based on Deep Learning , 2017, ICIC.

[35]  Aktham Hasan Ali,et al.  A smart monitoring and controlling for agricultural pumps using LoRa IOT technology , 2019, Indonesian Journal of Electrical Engineering and Computer Science.

[36]  Yoshito Tobe,et al.  Link-Correlation-Aware Opportunistic Routing in Wireless Networks , 2015, IEEE Transactions on Wireless Communications.

[37]  Tingting Wang,et al.  A self-calibrating sun tracker based on a differential pressure control system , 2013, 2013 International Conference on Materials for Renewable Energy and Environment.

[38]  Gerald E. Brust,et al.  Mites: Biology, Ecology, and Management , 2018 .

[39]  Jiannong Cao,et al.  Accurate Analytical-Based Multi-Hop Localization With Low Energy Consumption for Irregular Networks , 2020, IEEE Transactions on Vehicular Technology.

[40]  Rosemary Collier Pest and disease prediction models , 2017 .

[41]  Zhang Jingcheng,et al.  Research progress of crop diseases and pests monitoring based on remote sensing , 2012 .

[42]  Linghe Kong,et al.  Concurrent Transmission Aware Routing in Wireless Networks , 2018, IEEE Transactions on Communications.

[43]  Aiguo Song,et al.  DV‐hop localisation algorithm based on optimal weighted least square in irregular areas , 2018, Electronics Letters.

[44]  Morten Stigaard Laursen,et al.  Designing and Testing a UAV Mapping System for Agricultural Field Surveying , 2017, Sensors.

[45]  Xiang Li,et al.  Analysis of the development trends and innovation characteristics of Internet of Things technology – based on patentometrics and bibliometrics , 2020, Technol. Anal. Strateg. Manag..

[46]  Wang Xiao,et al.  An early warning system of diseases and pests for blueberry based on WSN , 2017, 2017 36th Chinese Control Conference (CCC).

[47]  Jing-Li Luo,et al.  Features of electrochemical noise generated during pitting of inhibited A516-70 carbon steel in chloride solutions , 1998 .

[48]  Andreas von Tiedemann,et al.  Linking Plant Disease Models to Climate Change Scenarios to Project Future Risks of Crop Diseases: A Review , 2015 .

[49]  M. P. Dayan,et al.  Survey, identification and pathogenicity of pests and diseases of bamboo in the Philippines. , 1988 .

[50]  K. N. Reddy,et al.  UAV Low-Altitude Remote Sensing for Precision Weed Management , 2017, Weed Technology.

[51]  Wei Li,et al.  Application of 3S Technology to Land Consolidation in Chernozem Region of China , 2008, CCTA.