Ultrasonic vibration technology has recently been applied in hot embossing process. High energy of ultrasonic vibration have been used to increase the temperature of the specimen so that material formability could be improved. Unlike polymer materials, very few research has been studied effect of ultrasonic vibration on hot glass embossing process. Experimental research has delineated the effects of ultrasonic vibration on reducing required forces and improving the formability of materials. Although numerical analysis of conventional glass molding, also glass hot embossing, using finite element method has been carried out deeply, it is inconvenient to utilize these material models for ultrasonic vibration-assisted hot glass embossing process due to the appearance of ultrasonic vibration. Therefore, the purpose of this study was to construct a finite element model for the ultrasonic vibration-assisted hot glass embossing process. The proposed model was used to explain experimental phenomena, such as reduction of embossing force during the embossing stage and the improvement of filling ability of glass material into the microcavities under effect of ultrasonic vibration. In order to construct the finite element model for the ultrasonic vibration-assisted hot glass embossing process, this study firstly utilized theoretical background relating to the dynamic response of glass material to explain the glass behavior during the embossing stage assisted by ultrasonic vibration. By predicting loss modulus of the glass from constitutive equation of Standard Linear Solid model, ultrasonic vibration absorption of the glass was calculated. The amount of energy which the glass absorbed from ultrasonic vibration was assumed to convert into heat completely. This heat generation was then inputted to finite element simulations through a thermal boundary condition. Instead of performing mechanical displacement of ultrasonic vibration, adding such thermal boundary condition could illustrate the reduction of embossing force as well as the improvement of filling ability of the glass into microcavities. The proposed finite element model was verified with experimental data. Using K-PSK100 optical glass specimens, flat hot embossing and microstructure hot embossing experiments were carried out with and without the assistance of ultrasonic vibration (amplitude of 3 m, frequency of 35 kHz) to express effect of ultrasonic vibration on embossing force and filling ability of glass material, respectively. Experimental results showed that ultrasonic vibration could reduce the embossing force significantly (up to 74.9 %) as well as help glass fill into the microcavities better (up to 17 %). Comparisons of embossing force response and the final height of pyramid structure between simulations and experiments were performed. Simulated results fitted quite well with experimental data, which validated the proposed model. Based on this proposed model, effect of some parameters such as embossing temperature, embossing speed, lower mold geometry and relaxation properties of the glass were also investigated. The findings of this research may be used to study effect of some other parameters, such as vibration frequency, vibration amplitude, the ultrasonic vibration applying time, etc., on the quality of the final product. Keywords: ultrasonic vibration, hot glass embossing, finite element analysis, pyramid microstructures