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Dynamics of a non-linearly damped microresonator under parametric excitation and its application in developing sensitive inertial sensors with ultra-wide dynamic ranges
S. Amir Mousavi Lajimi,
Michael Friswell
International Journal of Non-Linear Mechanics, Volume: 123, Start page: 103491
Swansea University Author: Michael Friswell
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DOI (Published version): 10.1016/j.ijnonlinmec.2020.103491
Abstract
We model and investigate the response of a nonlinear cantilever beam under principal parametric excitation. The design is initially assessed, optimized, and tuned using three-dimensional finite element analysis (FEA) to ensure the presence of fundamental parametric resonance and the absence of other...
| Published in: | International Journal of Non-Linear Mechanics |
|---|---|
| ISSN: | 0020-7462 |
| Published: |
Elsevier BV
2020
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| Online Access: |
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| URI: | https://cronfa.swan.ac.uk/Record/cronfa54221 |
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2020-05-14T19:08:28Z |
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2023-01-11T14:32:09Z |
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2022-11-15T16:12:11.9652212 v2 54221 2020-05-14 Dynamics of a non-linearly damped microresonator under parametric excitation and its application in developing sensitive inertial sensors with ultra-wide dynamic ranges 5894777b8f9c6e64bde3568d68078d40 Michael Friswell Michael Friswell true false 2020-05-14 We model and investigate the response of a nonlinear cantilever beam under principal parametric excitation. The design is initially assessed, optimized, and tuned using three-dimensional finite element analysis (FEA) to ensure the presence of fundamental parametric resonance and the absence of other internal and higher-order parametric resonances. The derived governing differential equation represents a modified generalized parametrically excited dynamic system under principal parametric excitation. The nonlinear dynamic system is developed and presented in the context of resonators with extensive applications in developing sensors, filters, and switches. The quadratic and cubic nonlinearities include second- and third-order deflection, velocity, acceleration terms describing stiffness, damping, and inertial nonlinearities. To explore and investigate the corresponding generalized nonlinear Mathieu equation, the method of multiple-scales along with the reconstitution method are used and modulation equations are obtained and solved to obtain closed-form amplitude and phase equations. The quadratic damping is modeled and approximated using a Fourier series and analytical models are generated in both Cartesian and Polar frames. To further explore the dynamic system and its applications, a resonator is designed to measure external acceleration and investigated for two cases. It is discussed and shown how the external acceleration modifies the dynamic system, the corresponding reduced-order model, and the modulation equations. The external acceleration affects the amplitude, phase, and frequency of oscillation providing means to estimate the input. These results indicate that the proposed resonator design (dynamic system) is able to significantly improve the dynamic range of shock/acceleration sensors. Journal Article International Journal of Non-Linear Mechanics 123 103491 Elsevier BV 0020-7462 Generalized parametric resonance, Nonlinear dynamic, Quadratic damping, Inertial and stiffness nonlinearity, Bifurcation, Sensors, FEA 1 7 2020 2020-07-01 10.1016/j.ijnonlinmec.2020.103491 COLLEGE NANME COLLEGE CODE Swansea University 2022-11-15T16:12:11.9652212 2020-05-14T13:29:20.8982121 Faculty of Science and Engineering School of Engineering and Applied Sciences - Uncategorised S. Amir Mousavi Lajimi 1 Michael Friswell 2 54221__17235__fad7cdef323f46759174748683230339.pdf 54221.pdf 2020-05-14T16:21:27.5268174 Output 990648 application/pdf Accepted Manuscript true 2021-04-23T00:00:00.0000000 © 2020. This manuscript version is made available under the CC-BY-NC-ND 4.0 license. true English http://creativecommons.org/licenses/by-nc-nd/4.0/ |
| title |
Dynamics of a non-linearly damped microresonator under parametric excitation and its application in developing sensitive inertial sensors with ultra-wide dynamic ranges |
| spellingShingle |
Dynamics of a non-linearly damped microresonator under parametric excitation and its application in developing sensitive inertial sensors with ultra-wide dynamic ranges Michael Friswell |
| title_short |
Dynamics of a non-linearly damped microresonator under parametric excitation and its application in developing sensitive inertial sensors with ultra-wide dynamic ranges |
| title_full |
Dynamics of a non-linearly damped microresonator under parametric excitation and its application in developing sensitive inertial sensors with ultra-wide dynamic ranges |
| title_fullStr |
Dynamics of a non-linearly damped microresonator under parametric excitation and its application in developing sensitive inertial sensors with ultra-wide dynamic ranges |
| title_full_unstemmed |
Dynamics of a non-linearly damped microresonator under parametric excitation and its application in developing sensitive inertial sensors with ultra-wide dynamic ranges |
| title_sort |
Dynamics of a non-linearly damped microresonator under parametric excitation and its application in developing sensitive inertial sensors with ultra-wide dynamic ranges |
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5894777b8f9c6e64bde3568d68078d40 |
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5894777b8f9c6e64bde3568d68078d40_***_Michael Friswell |
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Michael Friswell |
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S. Amir Mousavi Lajimi Michael Friswell |
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International Journal of Non-Linear Mechanics |
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123 |
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103491 |
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2020 |
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10.1016/j.ijnonlinmec.2020.103491 |
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Elsevier BV |
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| description |
We model and investigate the response of a nonlinear cantilever beam under principal parametric excitation. The design is initially assessed, optimized, and tuned using three-dimensional finite element analysis (FEA) to ensure the presence of fundamental parametric resonance and the absence of other internal and higher-order parametric resonances. The derived governing differential equation represents a modified generalized parametrically excited dynamic system under principal parametric excitation. The nonlinear dynamic system is developed and presented in the context of resonators with extensive applications in developing sensors, filters, and switches. The quadratic and cubic nonlinearities include second- and third-order deflection, velocity, acceleration terms describing stiffness, damping, and inertial nonlinearities. To explore and investigate the corresponding generalized nonlinear Mathieu equation, the method of multiple-scales along with the reconstitution method are used and modulation equations are obtained and solved to obtain closed-form amplitude and phase equations. The quadratic damping is modeled and approximated using a Fourier series and analytical models are generated in both Cartesian and Polar frames. To further explore the dynamic system and its applications, a resonator is designed to measure external acceleration and investigated for two cases. It is discussed and shown how the external acceleration modifies the dynamic system, the corresponding reduced-order model, and the modulation equations. The external acceleration affects the amplitude, phase, and frequency of oscillation providing means to estimate the input. These results indicate that the proposed resonator design (dynamic system) is able to significantly improve the dynamic range of shock/acceleration sensors. |
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2020-07-01T14:01:38Z |
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11.247077 |