With the development of technology, service robots will gradually come into our daily life. To work for people in indoor environment, service robots must have the ability to move across various indoor terrains and cope with different indoor environment. As a result, the purpose of this thesis is to develop an indoor mobile robot system with focus on stair climbing ability for service applications. Since stair climbing is always a hot topic in robotics, various stair-climbing mechanisms, such as track-based, wheel-legged, or humanoid solutions, are developed. However, for indoor service robots to perform tasks across floors, there are some requirements or limitations that those existed robot platforms cannot match. For example, to interact with human naturally, it is better for a service robot to have similar height as humans. And to move around indoor environment smoothly, the robot should have small footprint and high mobility. Unfortunately, those track-based stair-climbing robots usually lie on the floor, and the wheel-legged stair-climbing robots do not have small footprint or good mobility comparing to basic differential-wheeled platforms. Humanoid robots may be good solutions, but they are too complicated and stability is a concern. As a result, we design a mobile robot with proper locomotion and control strategy to meet all the requirements for stair-climbing service robots. There are several advantages of our robot. The design of high center of mass, tilt axis near ground, and the triangular wheel-legged structure enable the robot to climb stairs in a dynamic and self-balancing way. The triangular-shaped wheel-legged mechanism also keep the advantages of differential-wheeled mobile platforms when moving on flat ground, such as easy to control, saving power, and zero turning radius. Moreover, the overall mechanical design fits the requirements for a service robot to have proper height and small footprint, which can make human-robot interaction more natural and comfortable. Since the 3D perceptual and control system of the robot are both well integrated, we successfully demonstrate the stair-climbing function and prove that the design and implementation of our work are feasible and efficient.