In recent years, the world is demanding the manufacturer to reduce plastics. As one of the best solution, foamed products reduce use of plastics, while exhibiting excellent mechanical properties, electrical insulation, heat insulation, shock absorption and sound insulation. However, all of the properties mentioned above were related to the structure of bubbles, which requires comprehensive numerical models to estimate the bubble structure and the product characteristic before forming. This study is devoted to the validation of the numerical CAE software of Moldex3D that is mainly divided into two sections : the comparison of the simulation results with the visualization in literature, and with the actual forming experiments. The former study was conducted to investigate the effect of molding parameters on the cell structure in high-pressure injection molding and core-back technology. In the high-pressure injection molding, the simulation results were consistent with the visualization results, and the bubble dynamic behaviors were also in agreement with the visualization results.Moldex3D can effectively identify the influence of molding parameters on the structure of the bubble. But in the core-back injection molding, the CAE software obviously can’t determine the final structure of the bubbles. The reason is that the pressure gradient is non-isotropic and the heat transfer effect in the mold is more complicated because of the single-mold directional movement of the core-back technique and the skin layer generated during the core-back. The latter section was the experimental validation of simulation using Moldex3D. The comparison is evaluated whether the simulation software can effectively identify key molding parameters and the contributions of these parameters in high pressure injection molding and core-back by Taguchi's method with L9 table. In the high pressure injection molding, the simulation can effectively evaluate every molding parameter’s influence to the cell density, but is unable to determine its diameter. The cell size is not uniform in actual injection molding, while the CAE software assumes the bubbles to grow in a spherically symmetric manner. In the core-back experimental validation, the CAE software can’t evaluate the foaming behavior in core-back. The reason is that the heat transfer effect in the mold is more complicated because of the single-mold directional movement of the core-back technique and the skin layer generated during the core-back. It caused numerical model unable to evaluate the foaming behavior in core-back.