Abstract The purpose of this thesis is to develop an unmanned-vehicle system capable of accurate positioning, obstacle detection, and collision avoidance. The whole system consists of three parts: base station, reference station, and moving vehicle. On the moving vehicle, a servo motor system is used to do motion control; ultrasonic sensors and a stereo camera are adopted for obstacle detection; an electronic compass and a GPS receiver are installed for vehicle positioning. On the reference station, another GPS receiver is used to provide more positioning data. The main station can monitor and control the unmanned vehicle. For accurate positioning, a pair of GPS receivers can allow us calculate the vehicle position by Difference technique. By using the LAMBDA method (Least-squares Ambiguity Decorrelation Adjustment), we can resolve the integer ambiguity problem in an efficient process. Using Kalman Filter can further improve the performance of positioning, and the kinematic date of the vehicle can be obtained. For obstacle-avoiding, we integrate the stereo camera system to detect and locate the obstacles in front of the vehicle, and ultrasonic sensors to detect nearby obstacles. After detecting the obstacles, a map of obstacles is then built, and a feasible path to the destination can be designed by applying the RRT(Rapidly-Random-Tree) technique. Experimental results show that the design process is sound, and the unmanned vehicle can indeed follow the path to the destination without colliding with obstacles.