- The paper presents a model pipeline enhancing UAV active perception and motion control using low-cost RGB sensors and advanced computer vision.
- The system architecture integrates YOLOv8, a novel ActivePerceptionNet CNN, and an Extended Kalman Filter for robust object detection, localization, and navigation.
- Simulation results demonstrate accurate height/depth estimation (e.g., 0.06m error for wind turbines) and increased detection confidence, showing potential for cost-efficient real-world applications.
UAV Active Perception and Motion Control Using Low-Cost Sensors
This paper presents a sophisticated model pipeline that enhances the active perception and motion control of Unmanned Aerial Vehicles (UAVs) specifically integrating low-cost sensory systems. The paper is centered on deploying a computer vision-based framework utilizing low-cost RGB sensors integrated through the Microsoft AirSim simulator to improve the navigation of UAVs towards distinct objects, such as wind turbines and electric towers. The authors propose an intricate combination of the YOLOv8 object detection model and a novel CNN architecture, ActivePerceptionNet, to advance perception-aware UAV motion control.
Technical Implementation
The developed system architecture divides into three main modules: Object Tracking, Extended Kalman Filter (EKF) Localization, and Planning and Control. The primary sensory data stems from RGB imagery, IMU, and GPS measurements, tying in the drone's home position to construct a world-referenced coordinate system.
The YOLOv8 model initiates the detection process, providing base-level object localization, where subsequent algorithms refine the UAV's target approach utilizing height and depth estimations. The convolutional neural network, ActivePerceptionNet, further enhances detection operations through proactive inference, mitigating detection uncertainties from rotating structures like wind turbine propellers. This accounts for periodic downturns in confidence scores typically impacting detection performance.
Key Numerical Outcomes
Simulation results underscored the system's capacity for accurate height and depth estimations with low computational burden. Specifically, the authors report an average height estimation error of approximately 0.06 meters for wind turbines and 0.89 meters for electric towers. Highlighting the increased detection confidence level, nearly peaking the model's capacity, their ActivePerceptionNet integration proved effective, especially within the periodic motion context of wind turbines.
Implications and Future Directions
The implications for UAV active perception systems expand across civil and commercial applications, where cost-efficient and reliable navigation solutions are in heightened demand. The integration of low-cost sensors with advanced perception and control algorithms demonstrates feasible applications in photorealistic simulation environments with potential adoption in real-world scenarios.
Future work could explore real-life validations, extending the algorithm's adaptability across various UAV setups and environmental conditions. The exploration of further sensor types and integration methodologies may enrich the UAVs' perceptual robustness, enhancing overall operational efficacy across diverse operational fields.
In summary, the presented paper offers a perceptive evolution for UAV navigation systems by bridging the gap between advanced computer vision and robust control mechanics using economically accessible sensor frameworks. This work poses a promising avenue for engendering scalable and efficient UAV systems for complex navigational tasks in diverse fields of operation.