With the advancement of technology and concern for environmental protection, the requirements for fuel-efficient and lightweight automotive structures and the attention to automotive safety have been increasing. Therefore, increasing the strength and reducing the weight of the car body has become the goal that manufacturers put effort into. Advanced high-strength steel has an excellent combination of strength and plasticity and has been widely used in automotive structural parts. However, advanced high-strength steels are prone to the occurrence of edge cracks during stamping, which is still difficult to be predicted through finite element method simulation. The forming limit curve that is usually used to predict forming failure cannot effectively predict edge cracking. Therefore, in order to understand the phenomenon of edge cracking, this thesis will explore the influence of the sheared cross-section characteristics on edge cracking through the experimental analysis method. This thesis starts by collecting the documents on the causes of edge cracking and summarizes that the mechanism which affects the timing is complicated. In addition to the micro-structures that are prone to generating micro-voids in AHSS, the edge of the sheet will have different timings of edge cracking under different shearing processes. Furthermore, it is also known that the local formability of the hole tensile test and the hole expansion test can correspond to each other effectively, so that the failure criterion can be established through the hole tensile test. The related experiments are conducted in this thesis. By the establishment of the experiment and finite element method simulation model of hole tensile test, this thesis has obtained the maximum principal strain of different materials under different punching conditions and defined the maximum principal strain as the failure criterion, which also determined the local formability under different punching conditions. In the punching experiment, the trend of punching cross-section characteristics of different materials was observed respectively, which are compared with the trend of local formability obtained by the hole tensile test. It is known that the hardness difference of shear-affected zone has negative correlation with the local formability. Through the proportional relationship between hardness and stress, it can be observed that the stress has the same changing trend in the established punching simulation model. In the future, the failure criterion and simulation model established in this thesis can predict the timing of edge crack happening on real-case stamped part and also become a reference for improving the punching process.