Abstract
The purpose of this paper was to predict the path loss characterization of the ground-to-air (G2A) communication channel between the ground sensor (GS) and unmanned aerial vehicle (UAV) using machine learning (ML) models in smart farming (SF) scenarios. Two ML algorithms such as support vector regression (SVR) and artificial neural network (ANN) were studied to analyze the measured data in different scenarios with Napier and Ruzi grass farms as the measurement locations. The proposed empirical GS-to-UAV two-ray (GUT-R) model and the ML models were compared to characterize path loss prediction models. The performances of the path loss prediction models were evaluated using the statistical error indicators in different measurement locations and UAV trajectories. To obtain the statistical error indicators, the accuracy path loss results of UAV trajectory at 2 m altitudes showed the SVR model (MAE = 1.252 dB, RMSE = 3.067 dB, and R2 = 0.972) and the ANN model (MAE = 1.150 dB, RMSE = 2.502 dB, and R2 = 0.981) for the Napier scenario. In the Ruzi scenario, the SVR model (MAE = 1.202 dB, RMSE = 2.962 dB, and R2 = 0.965) and the ANN model (MAE = 1.146 dB, RMSE = 2.507 dB, and R2 = 0.983) were presented. For UAV trajectory at 5 m altitudes, the SVR model (MAE = 2.125 dB, RMSE = 4.782 dB, and R2 = 0.933) and the ANN model (MAE = 2.025 dB, RMSE = 4.439 dB, and R2 = 0.950) were resulted in the Napier scenario. In the Ruzi scenario, the SVR model (MAE = 2.112 dB, RMSE = 4.682 dB, and R2 = 0.935) and the ANN model (MAE = 2.016 dB, RMSE = 4.407 dB, and R2 = 0.954) were displayed. The proposed ML models using SVR and ANN can optimally predict the path loss characterization in SF scenarios, where the accuracy was 95% for the SVR and 97% for the ANN.
Highlights
SF is a global trend to produce new opportunities for agricultural farming
As a result of the prediction model, it is clear that the mean absolute error (MAE) of the SVR model is 1.636 dBm and 1.596 dBm for the ANN model
The path loss characteristics in realistic propagation SF scenarios for Ground sensor (GS)-to-UAV-enabled communication were studied by deploying ML models as the prediction models. e measurement data such as received signal strength indicator (RSSI) and path loss characteristics are experimentally investigated in different measurement locations such as Napier and Ruzi farm SF scenarios
Summary
SF is a global trend to produce new opportunities for agricultural farming. For agriculture 4.0, the solution of SF needs automation systems, robotics, information services, information and communication technologies (ICT), UAVused cases (both fixed- and rotary-wing), artificial intelligence (AI), big data analytics, and the Internet of things (IoT). UAV-based communications are the solution to raise the services in SF because it has rapidly expanded to all areas of agriculture, including pesticide and fertilizer spraying, seed sowing, monitoring, growth assessment, and mapping [1]. UAV applications in SF, such as mapping, spraying, planting, harvesting, irrigation, and crop monitoring, are existent. In [5], simultaneous localization and mapping (SLAM) technology in real-time mapping was presented using LiDAR to obtain data for low altitude imaginary. It can recognize the position and identify obstacles when the UAV tasks are performed. To monitor the data acquisition, UAVs are equipped with multifunctional sensors in a mobility network, especially in areas lacking mobile station networks in the field [6]
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