The purpose of this thesis is to conduct the experiment of the pseudo-rigid formation design algorithm on the motion of a multi-vehicle system. By integrating the hardware and path-programming algorithm, we are able to know the advantages and disadvantages of this formation design method for further design references. The algorithm adopted in this thesis applies the pseudo-rigid body theory to the formation design, which is determined by a homogenous deformation tensor such that rotation, stretch, and shear are allowed. This gives pseudo-rigid formation a better adaptability to environments of higher complexity, comparing to rigid body formation design. In the method, the Rapidly-Exploring Random Tree (RRT) method is first used along with the techniques of route adjustment to obtain the route of the system’s center. The deformation matrix is then found by using the method of virtual potential function, from which the route of each vehicle is computed. To implement the algorithm, customized vehicles are used, on which ultrasonic sensors, electric compass, motor encoder, Zigbee module, and motors are installed. We also utilize Microsoft’s Kinect to detect environmental objects, collaborating with ultrasonic sensors to detect obstacles. The vehicles’ positions and attitudes are calculated by motor encoder, and the controller on the vehicle uses Zigbee to exchange information with the computer. Route following is done by fuzzy control system for each vehicle and the coordinated control algorithm for the multi-vehicle system is designed. Experimental results show that the pseudo-rigid formation design algorithm for a multi-vehicle system is feasible.