The common defects present in the stamping of conventional steel sheets are fracture and wrinkling. However, the occurrence of springback, side-wall curl and distortion makes it more difficult to be solved in the stamping of advanced high strength steels. Among these problems, distortion plays a critical role in influencing the overall size difference of parts, resulting in the difficulty in welding and assembly process of the automobile parts. In order to cope with this dilemma, the finite element analysis is employed to help the tooling design so as to reduce the springback in the sheet forming process. Although previous studies have endeavored to establish the optimum simulation parameters, the accuracy in the prediction of springback is yet to be improved. Accordingly, this thesis investigates the optimum material model that describes the material behavior best to raise the accuracy of the finite element simulations on the prediction of springback and distortion.