In the recent years, there has been major interest in designing controllers of nonlinear and underactuated systems for the closed-loop stability and performance. Motivated by these facts, this thesis is going to design the balancing controller for the ball and arc system because this system is both nonlinear and underactuated. The system consists of a ball and a cart with the arc. The main control objective here is not only to drive the cart to bring the ball to stay on the top of the arc, but also to let the cart return to its origin. In the procedure of nonlinear backstepping design, the direct control design of this nonlinear system is quite difficult. In order to realize and analyze the properties of the ball and arc system, the linearized system model is introduced and investigated in the beginning. Then, according to the information we have obtained from designing the linearized system, the backstepping design scheme can be successfully developed for the nonlinear system to bring the ball to stay on the top of the arc and let the cart return to the origin. In addition, an adaptive backstepping design method is proposed to deal with the disturbance for the control of this ball and arc system. Our proposed nonlinear and adaptive controllers can achieve the control objectives and the resulting closed-loop system with proposed adaptive backstepping controller can have better performance than the system without adaptation. Finally, some simulation results are given to illustrate the excellent performance of the proposed controllers applied to the ball and arc system.