In recent years, with the development of Vehicular Ad Hoc Networks (VANETs) it is possible for the drivers to obtain lots of traffic information while they drive, and in turn both the driving safety and the traffic efficiency are enhanced. It has been shown that the performance of VANET applications is highly correlated to the vehicle’s positions, speed, and driving behaviors. In this thesis, we use the cellular automaton (CA) to accurately model the mixed traffic flows of both cars and scooters. There have been some similar studies in the literature which also utilize the CA to model car-only, scooter-only, or mixed traffic flows on the road; however, in these studies the traffic flows modeled are only for 1-dimensional road segments rather than for the more realistic 2-dimensional road topology with intersections. The CA is utilized in many fields such as vehicle mobility models, physics, and biology. For vehicle mobility models, it has usually been limited to model car-only scenarios. Some do consider mixed scenarios with both cars and scooters; however, the proposed models usually do not capture the nature of the actual traffic flows realistically. In this thesis, to address this problem we take the driver’s reactions into account and differentiate the physical dimensions and the acceleration and deceleration capabilities of cars and scooters. In the proposed model, the movements of cars and scooters in the mixed traffic flow are represented by the X-axis (parallel to the long side of the road) and the Y-axis (perpendicular to the long side of the road) velocities and locations at each time step. To show that our proposed model can generate realistic traffic flows, we also collect real-life traffic flow data from the roads using the LIDAR; comparison of the collected data and the simulator-generated traffic flows shows that car-following and lane-switching behaviors, how the vehicles react to traffic lights, and the turning trajectories of vehicles of both match well with each other. It has been shown that in VANETs, there will be significant additional signal attenuation when the propagation path between the transmitting vehicle and the receiving vehicle is blocked by any other vehicle; the link quality will be significantly lower. In this thesis, we propose two applications to utilize the proposed vehicle traffic mobility model. First, we propose a fast algorithm to calculate if there is any other vehicle blocking the propagation path between two vehicles. Second, statistics show that intersections are the most likely place where the collision can occur. We therefore propose an algorithm to predict the time and area of possible collisions at intersections. The algorithm can be utilized in future vehicle collision avoidance systems to lower the probability of accidents.