Dynamics of a clamped–clamped microbeam resonator considering fabrication imperfections

Bataineh, Ahmad; Younis, Mohammad I.

doi:10.1007/s00542-014-2349-7

Cited by 20 publications

(10 citation statements)

References 30 publications

(39 reference statements)

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“…This implies that this is a super harmonic resonance of order three. The phase portrait in Figure 6d shows two loops at 35 kHz, which also confirms a super harmonic resonance of order two [48].…”

Section: The Effect Of DC and Ac On The Super Harmonic Resonancessupporting

confidence: 59%

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Experimental investigation of snap-through motion of in-plane MEMS shallow arches under electrostatic excitation

Ramini

Bellaredj

Hafiz

et al. 2015

J. Micromech. Microeng.

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We present an experimental investigation for the nonlinear dynamic behaviors of clampedclamped in-plane MEMS shallow arches when excited by harmonic electrostatic forces. Frequency sweeps are conducted to study the dynamic behaviors in the neighborhoods of the first and third resonance frequencies as well as the super-harmonic resonances. Experimental results show local softening behavior of small oscillations around the first resonance frequency and hardening behavior at the third resonance frequency for small dc and ac loads. Interesting dynamic snap-through cross-well motions are observed experimentally at high voltages for the first time in the micro-scale world. In addition to the dynamic snap-through motion, the MEMS arch exhibits large oscillations of a continuous band of snap-through motion between the super-harmonic resonance regime and the first primary resonance regime. This continuous band is unprecedented experimentally in the micro/macro world, and is promising for a variety of sensing, actuation and communications applications.

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Section: The Effect Of DC and Ac On The Super Harmonic Resonancessupporting

confidence: 59%

“…The nonlinear equation governing the transverse motion w(x,t) of the arch microbeam shown in figure 1 [38][39][40][41][42][43][47][48][49] is as following…”

Section: Problem Formulationmentioning

confidence: 99%

Experimental investigation of snap-through motion of in-plane MEMS shallow arches under electrostatic excitation

Ramini

Bellaredj

Hafiz

et al. 2015

J. Micromech. Microeng.

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“…Next, we prove the inherent quadratic nonlinearity of the arch regardless of its actuation method (i.e., whether there is a DC electrostatic force or not), which shows a softening nonlinear response. The nonlinear equation governing the transverse motion w ( x , t ) of the arch beam based on no axial inertia can be written as [ 41 , 42 , 43 , 44 , 45 ]:

where x is the spatial position, t is time, and w 0 is the initial curvature of the arch. The arch has a Young’s modulus E , a material density ρ, and is assumed to have a rectangular cross-sectional area A and a moment of inertia I .…”

Section: Softening Nonlinearity In Arch Microbeammentioning

confidence: 99%

“…Here, we exploit the softening behavior in an arch-shaped beam for memory application. Unlike electrostatically actuated cantilever microbeams, where the softening nonlinear behavior is solely caused by the DC bias voltage, an arch shaped clamped–clamped microbeam shows softening nonlinearity due to its initial curvature [ 41 , 42 , 43 , 44 , 45 , 46 ]. Hence, the nonlinearity in this case is mainly of mechanical origin, and thus is almost independent of the DC bias (does not put any restriction on the amount of bias needed to trigger the nonlinearity), and can even be actuated using other methods, such as piezoelectric.…”

Section: Introductionmentioning

confidence: 99%

In-Plane MEMS Shallow Arch Beam for Mechanical Memory

et al. 2016

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We demonstrate a memory device based on the nonlinear dynamics of an in-plane microelectromechanical systems (MEMS) clamped–clamped beam resonator, which is deliberately fabricated as a shallow arch. The arch beam is made of silicon, and is electrostatically actuated. The concept relies on the inherent quadratic nonlinearity originating from the arch curvature, which results in a softening behavior that creates hysteresis and co-existing states of motion. Since it is independent of the electrostatic force, this nonlinearity gives more flexibility in the operating conditions and allows for lower actuation voltages. Experimental results are generated through electrical characterization setup. Results are shown demonstrating the switching between the two vibrational states with the change of the direct current (DC) bias voltage, thereby proving the memory concept.

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“…Although the model predicted the resonator behavior at low amplitudes, it failed to capture the response at high amplitude of vibration. In [32,33], it was shown that the shooting method is more robust and can predict the stable and unstable periodic solution accurately compared to Runge-Kutta, which depends on robustness and the size of the basin of attraction.…”

Section: Introductionmentioning

confidence: 99%

On the Nonlinear Dynamics of a Doubly Clamped Microbeam Near Primary Resonance

Jaber

Masri

Younis

2017

Journal of Vibration and Acoustics

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This work aims to investigate theoretically and experimentally various nonlinear dynamic behaviors of a doubly clamped microbeam near its primary resonance. Mainly, we investigate the transition behavior from hardening, mixed, and then softening behavior. We show in a single frequency–response curve, under a constant voltage load, the transition from hardening to softening behavior demonstrating the dominance of the quadratic electrostatic nonlinearity over the cubic geometric nonlinearity of the beam as the motion amplitudes becomes large, which may lead eventually to dynamic pull-in. The microbeam is fabricated using polyimide as a structural layer coated with nickel from top and chromium and gold layers from the bottom. Frequency sweep tests are conducted for different values of direct current (DC) bias revealing hardening, mixed, and softening behavior of the microbeam. A multimode Galerkin model combined with a shooting technique are implemented to generate the frequency–response curves and to analyze the stability of the periodic motions using the Floquet theory. The simulated curves show a good agreement with the experimental data.

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Dynamics of a clamped–clamped microbeam resonator considering fabrication imperfections

Cited by 20 publications

References 30 publications

Experimental investigation of snap-through motion of in-plane MEMS shallow arches under electrostatic excitation

Experimental investigation of snap-through motion of in-plane MEMS shallow arches under electrostatic excitation

In-Plane MEMS Shallow Arch Beam for Mechanical Memory

On the Nonlinear Dynamics of a Doubly Clamped Microbeam Near Primary Resonance

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