Drone Detection and Tracking Using RF Identification Signals

The market for unmanned aerial systems (UASs) has grown considerably worldwide, but their ability to transmit sensitive information poses a threat to public safety. To counter these threats, authorities, and anti-drone organizations are ensuring that UASs comply with regulations, focusing on strateg...

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Bibliographic Details
Published in:Sensors (Basel, Switzerland) Switzerland), 2023-09, Vol.23 (17), p.7650
Main Authors: Aouladhadj, Driss, Kpre, Ettien, Deniau, Virginie, Kharchouf, Aymane, Gransart, Christophe, Gaquière, Christophe
Format: Article
Language:English
Subjects:
Accuracy
Algorithms
Altitude
Analysis
C-UAS
Classification
Communication
Computer Science
Computer software industry
detection system
drone
Drone ID
Drones
Engineering Sciences
Global positioning systems
GPS
Localization
Machine learning
Methods
Neural networks
Open source software
Performance evaluation
Radio frequency
RF signal
Safety and security measures
Semiconductor industry
Sensors
Signal processing
Software utilities
Surveillance
UAV
Unmanned aerial vehicles
Wavelet transforms
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Summary:The market for unmanned aerial systems (UASs) has grown considerably worldwide, but their ability to transmit sensitive information poses a threat to public safety. To counter these threats, authorities, and anti-drone organizations are ensuring that UASs comply with regulations, focusing on strategies to mitigate the risks associated with malicious drones. This study presents a technique for detecting drone models using identification (ID) tags in radio frequency (RF) signals, enabling the extraction of real-time telemetry data through the decoding of Drone ID packets. The system, implemented with a development board, facilitates efficient drone tracking. The results of a measurement campaign performance evaluation include maximum detection distances of 1.3 km for the Mavic Air, 1.5 km for the Mavic 3, and 3.7 km for the Mavic 2 Pro. The system accurately estimates a drone’s 2D position, altitude, and speed in real time. Thanks to the decoding of telemetry packets, the system demonstrates promising accuracy, with worst-case distances between estimated and actual drone positions of 35 m for the Mavic 2 Pro, 17 m for the Mavic Air, and 15 m for the Mavic 3. In addition, there is a relative error of 14% for altitude measurements and 7% for speed measurements. The reaction times calculated to secure a vulnerable site within a 200 m radius are 1.83 min (Mavic Air), 1.03 min (Mavic 3), and 2.92 min (Mavic 2 Pro). This system is proving effective in addressing emerging concerns about drone-related threats, helping to improve public safety and security.
ISSN:1424-8220
1424-8220
DOI:10.3390/s23177650