With smart phones and tablet devices getting ever more popular, touch panel technology is becoming an essential feature of small and medium mobile devices. Despite the advancement of touch panel technology over the years, 3D acoustic panel technology still awaits for some break through. Unlike conventional touch panel, 3D acoustic panel is a touch-less technology. Touch-less technology does require user to touch the surface of the screen, the possible mechasim includingelectromagnetic, optical (imaging), and the ultrasonic types to detect the movement and gesture of user figners and hands. The ultrasonic type has the combined characteristics of low cost, supporting multi-touch, mounted on the existing panels as an add-on, and compatible with touch gestures, etc. when compared to other available technologies. All these characteristics have made ultrasound-based 3D panel a technology with high potential. The advantages become even more significant for large panels. The current leading technology such as capacitive touch technology faces low yield and high cost in this application domain. On the other hand, the ultrasonic 3D acoustic panel technology can potentially solve this issue effectively. With ultrasound 3D acoustic sensor/actuator remains in early development stage and most of the key technologies controlled by foreign companies, our industry possess no price advantage when facing international competition. A good ultrasonic transducer that can effectively improve the resolution and simplify the calculation of the amount of back-end algorithms can thus potentially become the key competitive advantage for developing large-size 3D acousti panels. In this paper, we will focus on the structure of touch sensor, using MEMS technology to produce a new type of Piezoelectric Micromachined Ultrasonic Transducer (PMUT). Unlike previous PZT deposition techniques such as sol-gel, screen printing and sputtering, we used aerosol deposition method to deposite PZT to achieve lower costs and rapid deposition. In addition, we tried to use stainless steel shim to replace the traditional silicon substrate based PMUT. The characteristics of the components developed were measured. To further refine the design parameters, we attempted to develop the reflectivity experiments so as to confirm the most suitable frequency range of skin sensitivity is between 55 kHz ~ 65 kHz. This finding will be used to further improve the design and fabrication process of 3D ultrasound panel technology in the future.