Abstract :
This paper describes the effect of design parameters of MEMS capacitive microphone on the static and dynamic behaviors. The aim is to develop the microphones with high sensitivity and flat frequency response. The high sensitivity can be obtained by changing the initial stress of diaphragm, sigmarmiddot diaphragm size, a, diaphragm thickness, t, back plate thickness, h, air gap thickness, d, back plate hole radius, r, surface area fraction occupied by the holes, a., and bias voltage. The equivalent electrical circuit method has been used to predict the structure behaviors and the microphone performance. The optimized structure has a diaphragm thickness of 0.8 mum, a diaphragm area of 2.43 mm2, an air gap of 4.0 mum and a 1.0 mum thick back plate with acoustical ports. The device shows maximum sensitivity of 47.9 mV/Pa, with a high frequency response extending to 18 kHz.
Keywords :
capacitive sensors; diaphragms; equivalent circuits; frequency response; micromechanical devices; microphones; MEMS capacitive microphone; design parameters; diaphragm stress; equivalent electrical circuit method; frequency 18 kHz; frequency response; microphone performance; size 0.8 mum; size 1.0 mum; structure behaviors; Capacitance; Circuits; Electric resistance; Frequency response; Micromechanical devices; Microphones; Noise level; Silicon; Stress; Voltage;
