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UAV_detection / README.md
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UAV Drone Detection and Tracking

Overview

This project detects UAV drones in video using a deep learning object detector and tracks them across frames using a Kalman filter. The output videos only include frames where the drone is present and overlay (1) the detector bounding box and (2) the 2D trajectory as a polyline.

Videos Used

Frames were extracted using ffmpeg at 5 FPS.

Dataset (Drone Bounding Boxes)

I used a dataset that labels the drone itself with bounding boxes (not aerial imagery “from a drone”).

  • Source: Roboflow (Drone Detection dataset)
  • Export format: YOLOv8
  • Class: drone

Detector (Task 1)

  • Model: Ultralytics YOLOv8n
  • Training: Fine-tuned on the drone bounding-box dataset
  • Best weights: runs/detect/train4/weights/best.pt
  • Inference: ran detection on every extracted frame
  • Deliverables created:
    • Frames containing detections saved to: artifacts/detections/<video_name>/
    • Detections saved to Parquet:
      • artifacts/detections/drone_video_1_detections.parquet
      • artifacts/detections/drone_video_2_detections.parquet

Kalman Filter Tracking (Task 2)

State Design

State vector: [x, y, vx, vy]

  • (x, y): bounding box center in pixel coordinates
  • (vx, vy): velocity in pixels/frame

Measurement vector: [x, y] from the detector.

Motion Model

A constant-velocity motion model is used:

  • Predict step uses x_t = x_{t-1} + vx * dt, y_t = y_{t-1} + vy * dt
  • Update step uses the detected center point when available

Handling Missed Detections

If the detector misses the drone temporarily, the tracker continues predicting without updates for a limited number of frames (max_missed). When detections return, the filter updates and continues the trajectory smoothly.

Visualization

Each output frame overlays:

  • The bounding box (detection if present; otherwise predicted)
  • The 2D trajectory polyline connecting the estimated centers across frames

Failure Cases

  • Small/far drones: detector can miss frames; Kalman prediction bridges short gaps.
  • Motion blur / fast motion: bounding boxes may jitter; filter smooths but can drift if misses last too long.
  • Background clutter: false positives can occur; increasing confidence threshold helps reduce them.