Phononic crystals (PC) are composite materials which consist of homogeneous elastic inclusions distributed periodically in a background medium characterized by different physical properties, such as mass density and elastic stiffness. Due to the special scattering effect in such a structure, there are many special properties existed. In this study, we investigate two different mechanisms that lead to the focusing in phononic crystal plates. One is based on the design of gradient index phononic crystal (GRIN PC) plate and the other one is based on the negative refraction effects. We numerically demonstrated the focusing behavior in the PC plates by the finite element method (FEM). For the case of the GRIN PC plate, the band structures and refraction indices (RI) of the GRIN PC plates with different filling fractions were calculated. And specific holes’ radii were designed to control the RI distribution to fit the hyperbolic secant curve. On the experimental side, focusing of the GRIN PC plates with two different scales was demonstrated. The experimental results show good agreements with those predicted from the numerical analyses. The second focusing mechanism is using the negative refraction effect in a PC plate which arranged in triangular lattice. In the analyses, the band structures and EFSs (equi-frequency surfaces) of the PC plates were calculated. The Snell’s law was introduced to predict the incident and refractive angles. Both the numerical analyses and experimental demonstrations were performed and the results also show good accordances.