As the effects of global warming intensify, lightweight has become an important approach to reducing carbon emissions. Aluminum alloys, due to their lightweight, high strength, good ductility, excellent corrosion resistance, good thermal and electrical conductivity, and ease of processing, are widely used in various fields. However, aluminum alloy materials often encounter streak defects during the production of extruded profiles, which is currently one of the most uncontrollable issues in the industry. This thesis aims to establish a finite element simulation model for the extrusion process with complex-shaped hollow cross-section aluminum extrusion dies. Through simulation, the study analyzes the stress conditions and temperature distribution during the extrusion process and, combined with material analysis experiments, investigates the possible factors causing surface streak defects on the profiles. This research employs DEFORM-3D finite element analysis software to analyze the aluminum alloy extrusion process, observing how streak defects are formed on the surface during extrusion, and identifying key factors that may lead to the occurrence of streaks based on the phenomena observed in material properties experiments. In the finite element model development, testing has shown that using a hyperbolic sine function equation to create material lists and selecting an absolute mesh for mesh generation is more suitable for extrusion simulation. This approach makes the simulation results more efficient and accurate. The analysis results show that the simulation results closely match the actual forming process in terms of extrusion load, the forming trend of the profile head, and the location of weld lines. This proves that DEFORM-3D has a certain degree of reliability in predicting profile deformation and the numerical accuracy of its analyses. In terms of material properties experiments, Electron Back Scatter Diffraction (EBSD) analysis reveals that the proportion of small-angle grain boundaries (2°~10°) is higher and the grain orientation is strongly directional in areas without streak defects. Roughness tests indicate that re-grinding with higher grit sandpaper at the streak defect locations can eliminate the defects. Hardness tests show that the hardness of normal areas is significantly higher than that of areas with streak defects. As to model analysis, it is observed that the high-temperature phenomenon in the thickness variation zone of the profile might be related to the larger particle size of the Mg2Si precipitates, while the streaks in the rib area might be related to the surface stress conditions. This thesis, through process parameter adjustments and die design modifications, found that the equivalent stress and temperature of the profile show regular changes during the extrusion process. When the container temperature is lower, the temperature distribution at the profile exit becomes more uniform, which helps to improve streaks caused by high-temperature in the thickness variation zone. This research helps to improve product appearance, increase production efficiency, reduce costs, and enhance product quality, providing both academic research contribution and industrial application value.