Abstract
Unmanned Aerial Vehicles (UAVs) have been widely applied for pesticide spraying as they have high efficiency and operational flexibility. However, the pesticide droplet drift caused by wind may decrease the pesticide spraying efficiency and pollute the environment. A precision spraying system based on an airborne meteorological monitoring platform on manned agricultural aircrafts is not adaptable for. So far, there is no better solution for controlling droplet drift outside the target area caused by wind, especially by wind gusts. In this regard, a UAV trajectory adjustment system based on Wireless Sensor Network (WSN) for pesticide drift control was proposed in this research. By collecting data from ground WSN, the UAV utilizes the wind speed and wind direction as inputs to autonomously adjust its trajectory for keeping droplet deposition in the target spraying area. Two optimized algorithms, namely deep reinforcement learning and particle swarm optimization, were applied to generate the newly modified flight route. At the same time, a simplified pesticide droplet drift model that includes wind speed and wind direction as parameters was developed and adopted to simulate and compute the drift distance of pesticide droplets. Moreover, an LSTM-based wind speed prediction model and a RNN-based wind direction prediction model were established, so as to address the problem of missing the latest wind data caused by communication latency or a lack of connection with the ground nodes. Finally, experiments were carried out to test the communication latency between UAV and ground WSN, and to evaluate the proposed scheme with embedded Raspberry Pi boards in UAV for feasibility verification. Results show that the WSN-assisted UAV trajectory adjustment system is capable of providing a better performance of on-target droplet deposition for real time pesticide spraying with UAV.
Highlights
Crop protection Unmanned Aerial Vehicles (UAVs) have achieved rapid development in recent years for their high pesticide spraying efficiency and strong environmental adaptation
A short-term wind speed and direction prediction model was presented. This is followed by the assessment that deep Q-network (DQN)-based and particle swarm optimization (PSO)-based UAV trajectory adjustment schemes can potentially be applied in pesticide drift control
Because this study focused on the method of adjusting the spraying route based on real-time wind speed and direction, a is focuseddroplet on the drift method of that adjusting theprimarily spraying on route based real-time wind and simplified model depends wind speedonand direction was speed proposed, direction, a simplified droplet drift model that depends primarily on wind speed and direction was while the UAV model, flight height and speed, as well as the droplet size and nozzle pressure were set proposed, while the UAV model, flight height and speed, as well as the droplet size and nozzle as fixed options
Summary
Crop protection UAVs have achieved rapid development in recent years for their high pesticide spraying efficiency and strong environmental adaptation. Based on the data sensed by the wireless sensor network deployed in the crop field, an architecture [33] and a computer-based system approach [34], which adjust the plant protection UAV route to changes in wind intensity and direction, were evaluated. Experimental results showed they can provide a more accurate deposition of pesticides. A short-term wind speed and direction prediction model was presented This is followed by the assessment that DQN-based and PSO-based UAV trajectory adjustment schemes can potentially be applied in pesticide drift control. A final section summarizes the conclusions and proposed directions for future research
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