Most conventional high-frequency vibrators generate the working power based on the piezoelectric and magnetostrictive effects. After entering the transducing system, the input time-varying electric energy will then be transferred into solid-body vibration; however, the heat dissipated has always been a critical issue of such vibrators. Therefore, the objective of this research was to develop a miniature high-frequency vibrator with high power output and high energy efficiency, which took advantage of the self-cooling property of gas and the pneumatic instability to trigger the vibration motion. Two aerostatic bearings were placed in the opposite configuration with the driven part oscillating back and forth due to the pneumatic hammer phenomenon. Full analysis was done by both theoretical calculation and finite element method. Predictions of load capacity, equivalent stiffness, and excited vibrating frequency were all proved possible and applicable while measurements of the unloading and loading characteristics of the vibrator were carried out by experiments. Besides, parameters including driven mass and spring loading effect were examined to a thorough understanding. In the end, modifications for the designed vibrator were proposed to acquire better system performance.