Conventional coil speakers have been developed for more than a century. However, expanding coil speakers into more futuristic applications often are limited by their weight and volume. Recently, flexible electret-based loudspeakers triggered many renewed interests due to their advantages over conventional coil speakers such as a simple and compact construction made from ultra-thin lightweight structures. Electret loudspeakers thus have many potential futuristic applications for 4C products (computers, communication, consumer electronics, and cars). The flexible electret-based loudspeaker presented in this dissertation consisted of spacer grids, back plates and electret membranes that were constructed by integrating many small capacitance type actuators to form an array structure. Simulations of electret cell actuator were used to derive the resonance and the corresponding modes. Since the low frequency performance of an electret loudspeaker is greatly affected by the first mode of each electret cell actuator, the shape and size of each cell actuator were tailored according to the specific requirements in order to vary the bandwidth of the electret loudspeaker for different applications. Furthermore, the performance is also mainly determined by the directivity of the electret loudspeaker. It was discovered that the novel electret loudspeaker possesses various directivities from a structural design aspect. Finite element analysis (FEA) was used to evaluate and to design the vibration mode and the directivity characteristics of the electret loudspeaker developed. AVID (advanced vibrometer/interferometer device) system and ESPI (electronic speckle pattern interferometry) system, both of which were non-destructive optical detection tools, were used to measure the vibration and the vibration mode shape of the electret cell actuators, respectively. A large-area surface potential measurement system was designed and constructed. A high bandwidth automatic acoustic measurement system was also developed to investigate the acoustic characteristic and directivity of the electret loudspeaker. Experimental results obtained confirmed the effectiveness of the simulation results. Finally, the sound characteristics of a flexible electret loudspeaker were tailored using the modeling and understanding obtained to improve the performance to the desired specifications. To further test the validity of the simulation and experimental model developed, applying the electret speakers in an automotive condition was attempted. To observe the SPL distribution at the passengers’ ears for loudspeakers installed at various locations, simulation model of the car cabin was first established. The performance of current vehicle installed coil speakers were compared to that of the newly developed electret loudspeaker. It was discovered both by simulation and by experimental verifications that the electret device possesses many advantages including installed locations, power consumption, sensitivity, volume, weight and flexibility when compared to that of the traditional coil speakers. The successful design, construction, and verification of the automotive used electret speakers provided a nice verification to the validity of the research results presented in this dissertation.