Porous PP film has superior mechanical properties due to its micro voids, including lightweight, flexible, and a high sensitivity. The porous structure allows it to store a large number of space charges and to have piezoelectric effect. Porous-electret has been applied in applications of sensors and actuators. For the application of actuators, it can provide a uniform distribution of space charges, a high energy efficiency, and low acoustic impedance. The resonance frequency of porous-electret is around 300 kHz, It makes it well suited to ultrasonic transducers. But, its low frequency response is poor due to its high flexibility and thin-thickness. In this thesis, we study the influence of porous structure to the acoustic performance of the porous electret film. Mechanical tension was applied to alter the flatness of voids This process can make the voids flatter, and it results in a wider frequency response and can extend to lower frequency region. Using this concept, a suction force was applied on an array of porous electret to change its curvature and to increase the flatness of voids. An infrared emitter was used to maintain the final curvature of each electret film. Scanning electron micrographs shows that this method can reduce ratio of porous diameter and height by 53.3 %. Experimental results also show that the acoustic response can be enhanced by using electret films with flatter voids. We also introduce bimorph structure to study its contributions to sound pressure. In the properties of the array device, the characteristic length of the cell was the main factor that effected on frequency response. If the cell size was increased, the sound pressure would increase and there would be better low frequency response. Experimental studies show that a 4 by 4 array with 12.5 mm in diameter circular cells can increase its sound pressure by an average of 9.9 dB after applying suction force. In the range between 1 kHz to 13 kHz, the sound pressure even enhanced 47 %. Moreover, a flatten area was observed between 1 kHz to10 kHz with the sound pressure reached 48 dB in average. For a 4 by 4 array with 15 mm in diameter circular cells, 1 kHz to 13 kHz, the sound pressure enhanced 34.3 % in the range between. In summary, the concept of using a flattened voids structure to enhance acoustic response of porous electret is verified. In the future, we hope this technology can be applied to flexible speakers with a wider bandwidth and low frequency response.