As IoT and Industry 4.0 take center stage, the demand for sensors is growing rapidly. Not only that, ultrasonic sensing technology also has been developing rapidly in recent years. Meanwhile, as the Microelectromechanical system (MEMS) process has gradually matured, the piezoelectric micromachined ultrasonic transducer (PMUT) with low cost, low power consumption, high output performance and miniaturization plays a crucial role in various fields. It is found that ultrasound applications exist everywhere, in consumer electronics, automotive electronics, smart factories and even medical ultrasound. However, compared to common ultrasonic products on the current market, such as medical ultrasound probes applying on tissue and airborne parking sensors, the current technology of airborne ultrasonic array radar is relatively immature. Therefore, this study will focus on developing airborne PMUT array to achieve higher performance than single element and realize spatial scanning by building three-dimensional spatial range detection system. The thesis is dedicated to developing PMUT array based on the applications of three-dimensional spatial range detection. The piezoelectric thick film is fabricated on stainless steel substrate by aerosol deposition method and then use MEMS process to finish the production of devices. The resonant frequency of PMUT array is at 56.9 kHz and the sound pressure level is about 106 dB at 6 cm distance. It also verifies the feasibility of PMUT phased array control. In the section of range detection, the maximum detection range of PMUT array up to 3 m and range error below 3 % by measurement results. Consequently, with the integration of phased array control and range detection technology, it can realize the three-dimensional spatial range detection.