Glass molding is a high-volume fabrication method suitable for producing optical components embedded in 3C products, such as optical glass lenses in the camera modules of mobile phones, digital cameras and projectors, etc. Despite the advantages of glass molding, several difficulties encountered in the manufacturing process have yet to be overcome. The most critical issue is the deviation between the formed lens and the original lens shape design. Thus, to overcome this obstacle, the focus of this dissertation is to introduce finite element analysis (FEA) into the prediction of the molded lens shape with detailed material models of the optical glass. To construct a comprehensive finite element (FE) model for the optical glass molding process, this study firstly performed experiments on the optical glass to obtain detailed material properties. Low Tg optical glass, L-BAL42 (Tg=506°C, Ohara Co.), was used in this research. Detailed thermal expansion coefficients including liquid and glassy states are obtained by thermal expansion experiment. Followed by using differential scanning calorimetry (DSC) and uniaxial compressive stress relaxation experiments, the structural relaxation property and the stress relaxation property were obtained respectively. Uniaxial compression test was also performed at the molding temperature (568°C, 30°C above At) to verify that the Newtonian fluid could accurately represent the glass flow behavior at molding stage. An aspherical optical glass lens molding experiment was then performed and the FEA with the same forming parameters was also conducted by using the commercial finite element program, MARC, incorporating these obtained material properties and the proposed material model. After verifying the consistency of simulated and experimental results, a comprehensive FE model for optical glass lens molding process was assured.