As increasing attention and concern are drawn to environmental preservation and sustainability, the lightweight design of automobiles becomes a major goal for vehicle manufacturers all around the globe. Lightweight vehicles also provide a solution relieving fuel inflation in recent years. In order to achieve vehicle lightweight design with cost minimization considered, the use of advanced high strength steels in automobile structural parts manufacture becomes a trend internationally. However, the increase in steel strength leads to greater obstacles concerning its formation, particularly when comparing to traditional low strength steel. Flaws in springback and side-wall curl also become more severe. Researches and studies have been carried out internationally on the development of advanced high strength steel material models, taking Bauschinger effect's work hardening criteria and yield criteria under biaxial stress into consideration. By gaining understanding of material properties during plastic deformation, hopefully better analysis on the stamping of advanced high strength steel can be achieved with springback prediction becoming more reliable. This research thus aims to explore the biaxial stretching plastic deformation of advanced high strength steel, and establish complete advanced high strength steel material models. Concerning work hardening criteria, research in Bauschinger’s effect often applies uniaxial specimens to carry out tension-compression tests to obtain its reversed stress status. However, in the actual stamping process, the sheet metal is usually subjected to bending and reversed bending deformation such as it passes through the draw bead or the die corner. This research therefore aims to explore the material properties of Bauschinger’s effect and deformation mechanism of advanced high strength steel under cyclic reversed bending deformation, and compare the findings with sheet metal tension-compression tests results. Three-point cyclic reversed bending clamping apparatus was in the same time designed and used to perform cyclic reversed bending experiments. The test data were compared with the finite element simulation results as a way to prove the necessity of the use of Yoshida-Uemori material model to describe the Bauschinger’s effect occurred in the stamping of advanced high strength steel sheets. This research also aims to explore the suitable yield criteria for advanced high strength steel subjected to biaxial stress states. Therefore, aspects on the characteristics of biaxial stretching plastic deformation are focused, in which the mechanisms of biaxial stretching on its equipment are targeted for improvement. The goal is to achieve better stability and ease installation during biaxial stretching tests. As for the biaxial specimen, specifications and restrictions for specimen shape and dimension are not available to date. The finite element analysis was then selected to determine the performance of biaxial stretching crossed-shaped specimen. The impact of specimen shape and geometric modeling on the measurement data was analyzed and used to design the most ideal cross-shaped specimen with slots for experimental purposes. Once achieving improvement on biaxial stretching mechanism and biaxial specimen, biaxial stretching test and clamping apparatus friction test were carried out. The experimental data obtained were used to explore the most suitable yield criteria for defining the plastic deformation behavior of advanced high strength steel under biaxial stress states. The yield criteria parameters for finite element analysis are established as the outcome. Finally, the Yoshida-Uemori model is taken into consideration for the selective combination with various yielding criteria, as means of simulating the stamping of basic and industrial vehicle carriers. The comparison of simulated and experimental results on material thickness and springback shows that the combination of Barlar 91 yield criterion with Yoshida-Uemori model is very effective in springback prediction of advanced high strength steel stamping.