The effect of the coupling radii of the elements of membrane MEMS systems on their own oscillations

The regularities of changes in the frequencies and forms of natural oscillations and the stress state of a silicon sensing element of a mechanical MEMS accelerometer system depending on changes in the radii of rounding of structural elements are considered. An increase in the natural frequencies of the system and stresses in torsion suspensions has been established with an increase in the radii of the coupling of the suspension with the frame and the inertial mass. The rounding of the shape of the suspensions in the plan leads to a decrease in natural frequencies and an increase in stresses arising from oscillatory movements. The fact of localization of high-frequency oscillation forms in the inertial mass is confirmed. A set of design solutions is recommended to control the vibration state of the MEMS accelerometer mechanical system.

1. Ausiyevich, A.M. The influence of the geometry of the silicon sensing element MEMS on its own vibrations. A.M. Ausiyevich, I.A. Taratyn, A.F. Smalyuk, P.S. Kirylau // Mathematical methods in technologies and engineering. Scientific Journal, No. 11, - St. Petersburg: Sarlen-Alex LLC, 2021. – pp. 71-75.

2. Gurtov V. A., Belyaev M. A., Baksheeva A.G. Microelectromechanical systems: Textbook. – Petrozavodsk: PetrSU Publishing House, 2016. – 171 p.

3. H. Lan, Y. Ding and H. Liu, Nanoimprint Lithography: Principles, Processes and Materials, Nova Science Publishing, 2011, pp. 73.

4. Sze S. M. Physics of Semiconductor Device. Third Edition / S. M. Sze, K. Ng Kwok, John Wiley & Sons, Inc., New Jersey, 2007. – 825 p.

5. Pautkin, V.E. Shaping of MEMS elements / Sensors and systems. No.8. 2018. – pp. 56-61.

6. Vibrations in technology: A reference book in the 6th edition / Ed. council: V.E. Chelomey (pred.). M.: Mechanical Engineering. 1978. Vol.1. – 352 p.

7. Strang G., Fix J. Theory of the finite element method. Moscow: Mir. 1977. – 352 p.

8. Hartmann F., Katz C. Structural analysis with finite elements. Springer. 2007. – 604 p.

9. Raspopov, V.Ya. Micromechanical devices. Study guide. 2nd ed., Tula State University, Moscow State Technological University named after K.E. Tsiolkovsky. Tula: Vulture and K. 2004. – 476 p.

10. Feodosiev, V.I. Resistance of materials: Studies for universities. - 10th edition, reprint. and additional - M.: Publishing House of the Bauman Moscow State Technical University, 1999. – 592 p.