Nonlinear vibration control with nanocapacitive sensor for electrostatically actuated nanobeam

The model of a clamped–clamped Euler–Bernoulli beam is presented in order to study nonlinear vibration control of electrostatically actuated nanobeam with nanocapacitive sensor, considering primary and superharmonic resonances. The capacitance of nanobeam capacitor changes with the nanobeam deformat...

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Bibliographic Details
Published inJournal of low frequency noise, vibration, and active control Vol. 37; no. 2; pp. 235 - 252
Main Authors Gong, Qingmei, Liu, Canchang, Xu, Yingzi, Ma, Chicheng, Zhou, Jilei, Jiang, Ruirui, Zhou, Changcheng
Format Journal Article
LanguageEnglish
Published London, England SAGE Publications 01.06.2018
Sage Publications Ltd
SAGE Publishing
Subjects
Amplitudes
Clamping
Computer simulation
Damping
Dynamic response
Euler-Bernoulli beams
Frequency response
Mathematical models
Multiscale analysis
Nanoelectromechanical systems
Nonlinear control
Nonlinear systems
Parameters
Sensors
Vibration
Vibration control
superharmonic resonance
Nonlinear vibration control
multiple scales method
primary resonance
nanobeam
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Summary:The model of a clamped–clamped Euler–Bernoulli beam is presented in order to study nonlinear vibration control of electrostatically actuated nanobeam with nanocapacitive sensor, considering primary and superharmonic resonances. The capacitance of nanobeam capacitor changes with the nanobeam deformation. The nanocapacitive sensor is applied to extract vibration signals and to transform enlarged signals into controller to control nanobeam vibrations. The method of multiple scales is used to obtain the first-order approximate solutions and derive the amplitude–frequency equation. The nonlinear vibration characteristics and amplitude–frequency response of nanobeam vibration system are studied under different excitation voltage, feedback gains, and damping. The relationships between amplitude and system parameters are discussed in detail. The presented analytical and numerical simulations show that dynamic response of nanobeam is stable when the appropriate parameters are chosen. This investigation provides a better understanding of the nonlinear vibration of nanoelectromechanical systems devices based on nanobeam.
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ISSN:1461-3484
2048-4046
DOI:10.1177/1461348417725953