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This study presents an AI-driven sensor framework to detect GPS spoofing in Unmanned Aerial Systems (UAS). The system ensures secure navigation and communication for drones, enhancing operational safety.

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Area of Science:

  • Aerospace Engineering
  • Artificial Intelligence
  • Cybersecurity

Background:

  • Unmanned Aerial Systems (UAS) are vital in civilian and defense sectors.
  • Reliance on unencrypted GPS signals makes UAS vulnerable to spoofing attacks, threatening safety and operations.

Purpose of the Study:

  • To introduce an AI-driven, multi-layer sensor framework for real-time GPS spoofing detection and secure command-and-control (C2) in UAS.
  • To enhance telemetry reliability and enable secure communication in resource-constrained UAS platforms.

Main Methods:

  • A refined preprocessing pipeline with GPS Drift Index (GDI), statistical normalization, oversampling, Kalman filtering, and quaternion filtering.
  • Differentiable Architecture Search (DARTS) for generating lightweight neural networks for onboard spoofing detection.
  • PRESENT-128 encryption and CMAC authentication for secure C2 communication.

Main Results:

  • The framework achieved outstanding detection accuracy (99.99%), F1-score (0.999), and AUC (0.9999).
  • Secure C2 communication with low latency (1.79 ms) and energy cost (0.51 mJ).
  • Demonstrated suitability for real-world, resource-constrained UAS environments.

Conclusions:

  • The AI-driven framework provides a robust, scalable, and secure solution for countering GPS spoofing in autonomous aerial vehicles.
  • This research advances AI-enabled sensor systems for enhanced UAS navigation and security.