Title :
A study on MEMS acoustic vibration sensor technology
Author :
Yonghe Qin ; Yingjie Qiao ; Wenjiang Zou ; Xingyue Xu
Author_Institution :
Inst. of Mater. Sci. & Chem. Eng., Harbin Eng. Univ., Harbin, China
Abstract :
By using ANASYS finite element analysis software to analyze the first three order resonance frequencies and strain values of the porous and porous free structure of the acoustic sensing chips, the optimization of the structure indicates: the resonance frequency of the porous structure varies lower relatively, but the stress improves relatively higher, we utilize beam membrane structure, the featured size of the beam thickness is 50 um. We utilize MEMS technology to fabricate acoustic vibration sensor chips on single crystalline silicon, and use second order vibration mode test unit to measure vibration signal, on condition of 5v power supply, the sensitivity of chip is about 26.8mV/g, resonance frequency is 5.19kHz, frequency response range is over 20~2000Hz, the frequency at the point of 3dB is 2.93kHz.
Keywords :
acoustic transducers; finite element analysis; microsensors; vibration measurement; ANASYS finite element analysis software; MEMS acoustic vibration sensor technology; acoustic vibration sensor chips; beam membrane structure; frequency 2.93 kHz; frequency 5.19 kHz; porous free structure; resonance frequency; second order vibration mode test unit; single crystalline silicon; size 50 mum; three order resonance frequency; vibration signal measurment; voltage 5 V; Acoustics; Resonant frequency; Semiconductor device measurement; Sensitivity; Sensors; Vibration measurement; Vibrations; MEMS; acoustic vibration; resonance frequency; sensor; single crystalline silicon;
Conference_Titel :
Optoelectronics and Microelectronics (ICOM), 2013 International Conference on
Conference_Location :
Harbin
Print_ISBN :
978-1-4799-1214-8
DOI :
10.1109/ICoOM.2013.6626490
