Object Detection and Tracking Using Uncalibrated Cameras

Amara, Ashwini

14 May 2010

This thesis considers the problem of tracking an object in world coordinates using measurements obtained from multiple uncalibrated cameras. A general approach to track the location of a target involves different phases including calibrating the camera, detecting the object's feature points over frames, tracking the object over frames and analyzing object's motion and behavior. The approach contains two stages. First, the problem of camera calibration using a calibration object is studied. This approach retrieves the camera parameters from the known locations of ground data in 3D and their corresponding image coordinates. The next important part of this work is to develop an automated system to estimate the trajectory of the object in 3D from image sequences. This is achieved by combining, adapting and integrating several state-of-the-art algorithms. Synthetic data based on a nearly constant velocity object motion model is used to evaluate the performance of camera calibration and state estimation algorithms.

Object detection and tracking

uncalibrated camera

camera calibration

perspective projection model

feature detection

Nonlinear least squares

lsqnonlin

estimation of camera parameters

azimuth and elevation angles

Vehicle detection and tracking using wireless sensors and video cameras

Bandarupalli, Sowmya

06 August 2009

This thesis presents the development of a surveillance testbed using wireless sensors and video cameras for vehicle detection and tracking. The experimental study includes testbed design and discusses some of the implementation issues in using wireless sensors and video cameras for a practical application. A group of sensor devices equipped with light sensors are used to detect and localize the position of moving vehicle. Background subtraction method is used to detect the moving vehicle from the video sequences. Vehicle centroid is calculated in each frame. A non-linear minimization method is used to estimate the perspective transformation which project 3D points to 2D image points. Vehicle location estimates from three cameras are fused to form a single trajectory representing the vehicle motion. Experimental results using both sensors and cameras are presented. Average error between vehicle location estimates from the cameras and the wireless sensors is around 0.5ft.

Surveillance testbed

vehicle detection and tracking

camera calibration

perspective projection model

wireless sensor measurements

Micaz

MoteView Nonlinear minimization

fminsearch

estimation of camera parameters

azimuth and elevation angles