To investigate the optimal kinematic characteristics of Geneva mechanism with radial straight slots at variable input speed and Geneva mechanism with curved slots at constant input speed, two methods are proposed for optimum design of the crank angular displacement function of the Geneva mechanism with radial straight slots at variable input speed and the wheel angular displacement function of the Geneva mechanism with curved slots at a constant input speed, respectively. In this study, minimizing the peak of four different objective functions for the optimum design are considered, respectively. They are the angular acceleration of the Geneva wheel, the input torque, the contact stress, and the degree of wear. 　　For convenience, the proposed methods are referred to as straight slot-variable input speed method and curved slot-constant input speed method. In this study, the crank angular displacement function is regarded as a function of time and the wheel angular displacement function is regarded as a function of the crank angular displacement. In this study, it is assumed the functions being designed are antisymmetric, thus only half of the functions need to be designed. Here, the domain of the function being designed is divided into several segments. Each segment is called an element, and both ends of each segment are called nodes. The nodal values of the function and its derivatives are used as design variables. The function being designed is assumed to be the Hermite interpolating polynomial in each element. In order to satisfy C2 continuity between elements, nth (n ) level Hermite interpolating polynomial is used. 　　The particle swarm optimization method is employed to solve the optimum problems. Design examples are given to demonstrate the effectiveness and practicability of the proposed method and to investigate the optimal kinematic characteristics of Geneva mechanism.