Theoretical and numerical modeling of a CMOS micromachined acoustic sensor

B. Mezghani, K. Haboura, F. Tounsi, S. Smaoui, Sami El-Borgi, S. Choura, M. Masmoudi

Research output: Chapter in Book/Report/Conference proceedingConference contribution

2 Citations (Scopus)

Abstract

In this paper, we present theoretical and numerical modeling done on a new structure of CMOS micromachined inductive microphone. Its mode of operation is based on the variation of the mutual inductance between an external fixed inductor and an internal suspended inductor. This internal inductor is designed on a 1.4×1.4mm2 suspended membrane. The displacement of the suspended membrane with two different attachment structures, the I-shaped and the L-shaped beams, is studied. Using a theoretical mechanical modeling, we get displacement values of 13.11μm and 68.82 μm, for the Ishaped and L-shaped beam design, respectively. With a numerical FEM analysis, using the Ansys software, displacement values of 12.7μm and 63.5 μm were found for the I-shaped and L-shaped beam design, respectively. Using the analogy between acoustic, mechanical and electrical domains, the dynamic behavior of the L-shaped beam design sensor is studied and a corner frequency around 200 kHz is found. This value is also found when applying analytical dynamics principles to determine the equations of motion for the suspended membrane. A FEM analysis, using the Ansys software, is conducted in order to validate this theoretical model.

Original languageEnglish
Title of host publicationProceedings - 2006 International Conference on Design and Test of Integrated Systems in Nanoscale Technology, IEEE DTIS 2006
Pages419-423
Number of pages5
Publication statusPublished - 2006
Externally publishedYes
Event2006 International Conference on Design and Test of Integrated Systems in Nanoscale Technology, IEEE DTIS 2006 - Tunis, Tunisia
Duration: 5 Sep 20067 Sep 2006

Other

Other2006 International Conference on Design and Test of Integrated Systems in Nanoscale Technology, IEEE DTIS 2006
CountryTunisia
CityTunis
Period5/9/067/9/06

Fingerprint

Acoustics
Membranes
Sensors
Finite element method
Microphones
Inductance
Equations of motion

Keywords

  • Acoustic sensor
  • CMOS
  • Micromachined
  • Numerical modeling
  • Suspended membrane

ASJC Scopus subject areas

  • Control and Systems Engineering
  • Electrical and Electronic Engineering
  • Safety, Risk, Reliability and Quality

Cite this

Mezghani, B., Haboura, K., Tounsi, F., Smaoui, S., El-Borgi, S., Choura, S., & Masmoudi, M. (2006). Theoretical and numerical modeling of a CMOS micromachined acoustic sensor. In Proceedings - 2006 International Conference on Design and Test of Integrated Systems in Nanoscale Technology, IEEE DTIS 2006 (pp. 419-423). [1708688]

Theoretical and numerical modeling of a CMOS micromachined acoustic sensor. / Mezghani, B.; Haboura, K.; Tounsi, F.; Smaoui, S.; El-Borgi, Sami; Choura, S.; Masmoudi, M.

Proceedings - 2006 International Conference on Design and Test of Integrated Systems in Nanoscale Technology, IEEE DTIS 2006. 2006. p. 419-423 1708688.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Mezghani, B, Haboura, K, Tounsi, F, Smaoui, S, El-Borgi, S, Choura, S & Masmoudi, M 2006, Theoretical and numerical modeling of a CMOS micromachined acoustic sensor. in Proceedings - 2006 International Conference on Design and Test of Integrated Systems in Nanoscale Technology, IEEE DTIS 2006., 1708688, pp. 419-423, 2006 International Conference on Design and Test of Integrated Systems in Nanoscale Technology, IEEE DTIS 2006, Tunis, Tunisia, 5/9/06.
Mezghani B, Haboura K, Tounsi F, Smaoui S, El-Borgi S, Choura S et al. Theoretical and numerical modeling of a CMOS micromachined acoustic sensor. In Proceedings - 2006 International Conference on Design and Test of Integrated Systems in Nanoscale Technology, IEEE DTIS 2006. 2006. p. 419-423. 1708688
Mezghani, B. ; Haboura, K. ; Tounsi, F. ; Smaoui, S. ; El-Borgi, Sami ; Choura, S. ; Masmoudi, M. / Theoretical and numerical modeling of a CMOS micromachined acoustic sensor. Proceedings - 2006 International Conference on Design and Test of Integrated Systems in Nanoscale Technology, IEEE DTIS 2006. 2006. pp. 419-423
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