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Meccanica

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01.09.2013

An electrically actuated imperfect microbeam: Dynamical integrity for interpreting and predicting the device response

verfasst von: Laura Ruzziconi, Mohammad I. Younis, Stefano Lenci

Erschienen in: Meccanica | Ausgabe 7/2013

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Abstract

In this study we deal with a microelectromechanical system (MEMS) and develop a dynamical integrity analysis to interpret and predict the experimental response. The device consists of a clamped-clamped polysilicon microbeam, which is electrostatically and electrodynamically actuated. It has non-negligible imperfections, which are a typical consequence of the microfabrication process. A single-mode reduced-order model is derived and extensive numerical simulations are performed in a neighborhood of the first symmetric natural frequency, via frequency response diagrams and behavior chart. The typical softening behavior is observed and the overall scenario is explored, when both the frequency and the electrodynamic voltage are varied. We show that simulations based on direct numerical integration of the equation of motion in time yield satisfactory agreement with the experimental data. Nevertheless, these theoretical predictions are not completely fulfilled in some aspects. In particular, the range of existence of each attractor is smaller in practice than in the simulations. This is because these theoretical curves represent the ideal limit case where disturbances are absent, which never occurs under realistic conditions. A reliable prediction of the actual (and not only theoretical) range of existence of each attractor is essential in applications. To overcome this discrepancy and extend the results to the practical case where disturbances exist, a dynamical integrity analysis is developed. After introducing dynamical integrity concepts, integrity profiles and integrity charts are drawn. They are able to describe if each attractor is robust enough to tolerate the disturbances. Moreover, they detect the parameter range where each branch can be reliably observed in practice and where, instead, becomes vulnerable, i.e. they provide valuable information to operate the device in safe conditions according to the desired outcome and depending on the expected disturbances.

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Senturia SD (2001) Microsystem design. Kluwer Academic, Dordrecht

Younis MI (2011) MEMS linear and nonlinear statics and dynamics. Springer, Berlin CrossRef

Towfighian S, Heppler GR, Abdel Rahman EM (2012) Low-voltage closed loop MEMS actuators. Nonlinear Dyn 69:565–575 CrossRef

Krylov S, Ilic BR, Schreiber D, Seretensky S, Craighead H (2008) The pull-in behavior of electrostatically actuated bistable microbeams. J Micromech Microeng 18:55026 CrossRef

Mestrom RMC, Fey RHB, van Beek JTM, Phan KL, Nijmeijer H (2008) Modelling the dynamics of a MEMS resonator: simulations and experiments. Sens Actuators A 142:306–315 CrossRef

Rhoads JF, Shaw SW, Turner KL, Moehlis J, DeMartini BE (2006) Generalized parametric resonance in electrostatically actuated microelectromechanical oscillators. J Sound Vib 296:797–829 ADSCrossRef

Gottlieb O, Champneys A (2005) Global bifurcations of nonlinear thermoelastic microbeams subject to electrodynamic actuation. In: Rega G, Vestroni F (eds) IUTAM symp. on chaotic dynamics and control of systems and processes in mechanics solid mechanics and its applications, vol 122. Springer, Berlin, pp 117–126 CrossRef

Alsaleem FM, Younis MI, Ouakad HM (2009) On the nonlinear resonances and dynamic pull-in of electrostatically actuated resonators. J Micromech Microeng 19:045013 CrossRef

Hornstein S, Gottlieb O (2012) Nonlinear multimode dynamics and internal resonances of the scan process in noncontacting atomic force microscopy. J Appl Phys 112:074314 ADSCrossRef

10.

DeMartini BE, Butterfield HE, Moehlis J, Turner KL (2007) Chaos for a microelectromechanical oscillator governed by the nonlinear Mathieu equation. J Microelectromech Syst 16:1314–1323 CrossRef

11.

De SK, Aluru NR (2006) Complex nonlinear oscillations in electrostatically actuated microstructures. J Microelectromech Syst 15:355–369 CrossRef

12.

Chavarette FR, Balthazar JM, Felix JLP, Rafikov M (2009) A reducing of a chaotic movement to a periodic orbit, of a micro-electro-mechanical system, by using an optimal linear control design. Commun Nonlinear Sci Numer Simul 14:1844–1853 ADSCrossRef

13.

Kniffka TJ, Welte J, Ecker H (2012) Stability analysis of a time-periodic 2-dof MEMS structure. In: AIP conf. proc. ICNPAA international conference on mathematical problems in engineering, aerospace and sciences, vol 1493, pp 559–566

14.

Dick AJ, Balachandran B, Mote CD Jr (2008) Intrinsic localized modes in microresonator arrays and their relationship to nonlinear vibration modes. Nonlinear Dyn 54:13–29 MATHCrossRef

15.

Cho H, Jeong B, Yu MF, Vakakis AF, McFarland DM, Bergman LA (2012) Nonlinear hardening and softening resonances in micromechanical cantilever-nanotube systems originated from nanoscale geometric nonlinearities. Int J Solids Struct 49:2059–2065 CrossRef

16.

Kozinsky I, Postma HWC, Kogan O, Husain A, Roukes ML (2007) Basins of attraction of a nonlinear nanomechanical resonator. Phys Rev Lett 99:201–207 CrossRef

17.

Virgin LN (2000) Introduction to experimental nonlinear dynamics: a case study in mechanical vibration. Cambridge University Press, Cambridge

18.

Thompson JMT (1989) Chaotic behavior triggering the escape from a potential well. Proc R Soc Lond Ser A 421:195–225 ADSMATHCrossRef

19.

Soliman MS, Thompson JMT (1989) Integrity measures quantifying the erosion of smooth and fractal basins of attraction. J Sound Vib 135:453–475 MathSciNetADSMATHCrossRef

20.

Lenci S, Rega G (2003) Optimal control of nonregular dynamics in a Duffing oscillator. Nonlinear Dyn 33:71–86 MathSciNetMATHCrossRef

21.

Lenci S, Rega G, Ruzziconi L (2013, in press) The dynamical integrity concept for interpreting/predicting experimental behavior: from macro- to nano-mechanics. Philos Trans R Soc

22.

Lansbury AN, Thompson JMT, Stewart HB (1992) Basin erosion in the twin-well Duffing oscillator: two distinct bifurcation scenarios. Int J Bifurc Chaos 2:505–532 MathSciNetMATHCrossRef

23.

Lenci S, Rega G (2004) A dynamical systems analysis of the overturning of rigid blocks. In: Proceedings of the XXI international conference of theoretical and applied mechanics, IPPT PAN, ISBN: 83-89687-01-1, Warsaw, Poland, August 15–21

24.

Ruzziconi L, Lenci S, I YM (2013, in press) An imperfect microbeam under an axial load and electric excitation: nonlinear phenomena and dynamical integrity. Int J Bifurc Chaos 23:1350026. doi:10.1142/S0218127413500260 CrossRef

25.

Rega G, Lenci S (2005) Identifying, evaluating, and controlling dynamical integrity measures in nonlinear mechanical oscillators. Nonlinear Anal TMA 63:902–914 MathSciNetMATHCrossRef

26.

Soliman MS, Thompson JMT (1991) Transient and steady state analysis of capsize phenomena. Appl Ocean Res 13:82–92 CrossRef

27.

Infeld E, Lenkowska T, Thompson JMT (1993) Erosion of the basin of stability of a floating body as caused by dam breaking. Phys Fluids 5:2315–2316 ADSMATHCrossRef

28.

De Souza JR, Rodrigues ML (2002) An investigation into mechanisms of loss of safe basins in a 2 D.O.F. nonlinear oscillator. J Braz Soc Mech Sci Eng 24:93–98

29.

De Freitas MST, Viana RL, Grebogi C (2003) Erosion of the safe basin for the transversal oscillations of a suspension bridge. Chaos Solitons Fractals 18:829–841 ADSMATHCrossRef

30.

Gonçalves PB, Silva FMA, Rega G, Lenci S (2011) Global dynamics and integrity of a two-d.o.f. model of a parametrically excited cylindrical shell. Nonlinear Dyn 63:61–82 MATHCrossRef

31.

Ruzziconi L, Younis MI, Lenci S (submitted). Multistability in an electrically actuated carbon nanotube: a dynamical integrity perspective

32.

Lenci S, Rega G (2011) Experimental versus theoretical robustness of rotating solutions in a parametrically excited pendulum: a dynamical integrity perspective. Physica D 240:814–824 ADSMATHCrossRef

33.

Ruzziconi L, Younis MI, Lenci S (2013) Dynamical integrity for interpreting experimental data and ensuring safety in electrostatic MEMS. In: Wiercigroch M, Rega G (eds) IUTAM symp. on nonlinear dynamics for advanced technologies and engineering, vol 32. Springer, Berlin, pp 249–261 CrossRef

34.

Alsaleem F, Younis MI, Ruzziconi L (2010) An experimental and theoretical investigation of dynamic pull-in in MEMS resonators actuated electrostatically. J Microelectromech Syst 19:794–806 CrossRef

35.

Settimi V, Rega G (2012) Bifurcations, basin erosion and dynamic integrity in a single-mode model of noncontact atomic force microscopy. In: Proceedings international conference on structural nonlinear dynamics and diagnosis, Marrakesh, Morocco, April 30–May 02, 2012. doi:10.1051/mateconf/20120104006

36.

Lenci S, Rega G (2006) Control of pull-in dynamics in a nonlinear thermoelastic electrically actuated microbeam. J Micromech Microeng 16:390–401 CrossRef

37.

Ruzziconi L, Bataineh AM, Younis MI, Cui W, Lenci S (submitted). An electrically actuated imperfect microbeam resonator. Experimental and theoretical investigation of the nonlinear dynamic response

38.

Ruzziconi L, Younis MI, Lenci S (submitted). Parameter identification of an electrically actuated imperfect microbeam

39.

Nusse HE, Yorke JA (1998) Dynamics. Numerical explorations. Springer, New York

Titel: An electrically actuated imperfect microbeam: Dynamical integrity for interpreting and predicting the device response
verfasst von: Laura Ruzziconi
Mohammad I. Younis
Stefano Lenci
Publikationsdatum: 01.09.2013
Verlag: Springer Netherlands
Erschienen in: Meccanica / Ausgabe 7/2013
Print ISSN: 0025-6455
Elektronische ISSN: 1572-9648
DOI: https://doi.org/10.1007/s11012-013-9707-x

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