In the past studies, the vibration energy harvesting technologies have been studied intensively and based on material of lead zirconate titanate (PZT). The power outputs of piezoelectric MEMS generators were steadily improved year by year. Until now, the performance of energy harvesters(EH) had gradually reached the limit of the chosen materials. In our previous research, a significant increase in power output was achieved by altering the EH substrate material. In view of this, we introduce innovative piezoelectric material in this dissertation to expect a breakthrough in the limit of EH energy output. According to recently published literature, attention has been given to lead magnesium niobate–lead titanate (PMN-PT) material because of its high piezoelectric constant and electromechanical coupling factor. In this dissertation, 10 m of PMN-PT film was successfully deposited on stainless steel substrate by aerosol deposition. First part of this dissertation is to investigate critical parameters of aerosol deposition method and we found the pre-process for starting powder is a key to deposit PMN-PT layer. Powder milled for 3 hours and heated at 450 oC were chosen as the best deposition condition. Then, in order to increase piezoelectric properties of the device, annealing and poling process were necessary and optimal parameters were described as below: annealed at 525 oC, electric field was 30 V/μm, poling temperature was 150 oC, and poling time was 20 minutes. The experimental results show that the fabricated device excited at 0.5 g vibration level can generate a maximum output voltage of 7.7 VPP and corresponding power of 90.4 μW at the resonant frequency of 98 Hz. When given a comparison with previous work, the output performance is better than the PZT-based EH with same thickness, which had maximum output voltage of 6.2 VPP and corresponding power of 48.5 μW under 0.5 g acceleration.