Counter-Drone Radar Technology

Introduction

Drone proliferation requires reliable detection. Radar is effective for identifying unauthorized drones.

Radar Fundamentals

Basic Principles

Radar transmits EM waves and analyzes reflections. Detection depends on power, gain, RCS, range.

Drone RCS

Consumer drones: 0.0001-0.01 sq meters, orders smaller than aircraft. Needs specialized detection.

Micro-Doppler

Blade Signatures

Rotating blades create micro-Doppler. Rates 2000-8000 RPM, spread 50-500 Hz.

Classification

ML distinguishes drones from birds using modulation, harmonics, patterns.

Doppler Types

CW Doppler

Continuous transmission detects shifts. Simple but needs modulation for range.

Pulsed Doppler

Short bursts measure delay for range. Combines range and velocity.

FMCW

Frequency-modulated CW determines range/velocity. Good resolution, lower cost.

Phased Array

Electronic Steering

Multiple elements steer beams without movement. Rapid scanning, multi-target.

AESA

Individual T/R modules per element. Superior reliability and beamforming.

Digital Beamforming

Processes all elements for multiple beams and cancellation.

Low-Altitude Challenges

Ground Clutter

Terrain creates clutter 60-80 dB stronger. Needs suppression.

Suppression

• MTI: Filters stationary
• STAP: Spatial-temporal
• Elevation discrimination
• Polarization diversity

LSS Detection

Characteristics

Low (below 120m), Slow (10-60 km/h), Small RCS. Conventional radars struggle.

Specialized

• Low grazing angle
• High PRF
• Wide bandwidth
• Cognitive radar

Bands

S-Band

2-4 GHz. Good balance. Common in commercial.

C-Band

4-8 GHz. Better resolution. More rain attenuation.

X-Band

8-12 GHz. High resolution. Affected by weather.

Multi-Static

Configurations

Separate TX/RX exploit aspects. RCS varies with angle.

Passive

Uses FM/TV/cellular. Covert, no licensing. Complex.

Conclusion

Micro-Doppler, phased arrays, fusion are best practices. Future: quantum, AI.