Modeling of Micromachined Beams Subject to Nonlinear Restoring or Damping Forces
Electrostatic, Casimir, or squeeze-film damping forces are some of the many inverse power-law forces that may affect micromachined devices. The behavior of structures that are subject to such forces, even simple ones such as clamped-clamped or cantilever beams, is difficult to model in a way that is...
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| Published in | Journal of microelectromechanical systems Vol. 20; no. 1; pp. 165 - 177 |
|---|---|
| Main Authors | , , |
| Format | Journal Article |
| Language | English |
| Published |
New York, NY
IEEE
01.02.2011
Institute of Electrical and Electronics Engineers The Institute of Electrical and Electronics Engineers, Inc. (IEEE) |
| Subjects | |
| Online Access | Get full text |
| ISSN | 1057-7157 1941-0158 |
| DOI | 10.1109/JMEMS.2010.2090650 |
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| Abstract | Electrostatic, Casimir, or squeeze-film damping forces are some of the many inverse power-law forces that may affect micromachined devices. The behavior of structures that are subject to such forces, even simple ones such as clamped-clamped or cantilever beams, is difficult to model in a way that is both computationally efficient and physically meaningful. The main contribution of this paper is a semianalytical modeling approach for microbeams that are subject to inverse power-law force densities, which is accurate, computationally efficient, and amenable to physical interpretation. This approach is based on the observation that, for large deformations, inverse power-law forces affect all mathematically equivalent shapes in the same way. Starting from reference shapes for which the analytical expressions of the Galerkin projection of the inverse power-law forces are known, semianalytical expressions are then established for all equivalent shapes, using a simple least squares fitting procedure. In a context of transient simulation, the resulting models are economical because they do not require costly deformation-dependent integral evaluations. Furthermore, they can be used to establish analytical expressions of relevant physical quantities. This approach is validated with simulated and experimental data and compared qualitatively and quantitatively to other reduced-order modeling methods. |
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| AbstractList | Electrostatic, Casimir, or squeeze-film damping forces are some of the many inverse power-law forces that may affect micromachined devices. The behavior of structures that are subject to such forces, even simple ones such as clamped-clamped or cantilever beams, is difficult to model in a way that is both computationally efficient and physically meaningful. The main contribution of this paper is a semianalytical modeling approach for microbeams that are subject to inverse power-law force densities, which is accurate, computationally efficient, and amenable to physical interpretation. This approach is based on the observation that, for large deformations, inverse power-law forces affect all mathematically equivalent shapes in the same way. Starting from reference shapes for which the analytical expressions of the Galerkin projection of the inverse power-law forces are known, semianalytical expressions are then established for all equivalent shapes, using a simple least squares fitting procedure. In a context of transient simulation, the resulting models are economical because they do not require costly deformation-dependent integral evaluations. Furthermore, they can be used to establish analytical expressions of relevant physical quantities. This approach is validated with simulated and experimental data and compared qualitatively and quantitatively to other reduced-order modeling methods. Electrostatic, Casimir, or squeeze-film damping forces are some of the many inverse power-law forces that may affect micromachined devices. The behavior of structures that are subject to such forces, even simple ones such as clamped-clamped or cantilever beams, is difficult to model in a way that is both computationally efficient and physically meaningful. The main contribution of this paper is a semianalytical modeling approach for microbeams that are subject to inverse power-law force densities, which is accurate, computationally efficient, and amenable to physical interpretation. This approach is based on the observation that, for large deformations, inverse power-law forces affect all mathematically equivalent shapes in the same way. Starting from reference shapes for which the analytical expressions of the Galerkin projection of the inverse power-law forces are known, semianalytical expressions are then established for all equivalent shapes, using a simple least squares fitting procedure. In a context of transient simulation, the resulting models are economical because they do not require costly deformation-dependent integral evaluations. Furthermore, they can be used to establish analytical expressions of relevant physical quantities. This approach is validated with simulated and experimental data and compared qualitatively and quantitatively to other reduced-order modeling methods.[2010-0128] Electrostatic, Casimir, or squeeze-film damping forces are some of the many inverse power-law forces that may affect micromachined devices. The behavior of structures that are subject to such forces, even simple ones such as clamped-clamped or cantilever beams, is difficult to model in a way that is both computationally efficient and physically meaningful. The main contribution of this paper is a semianalytical modeling approach for microbeams that are subject to inverse power-law force densities, which is accurate, computationally efficient, and amenable to physical interpretation. This approach is based on the observation that, for large deformations, inverse power-law forces affect all mathematically equivalent shapes in the same way. Starting from reference shapes for which the analytical expressions of the Galerkin projection of the inverse power-law forces are known, semianalytical expressions are then established for all equivalent shapes, using a simple least squares fitting procedure. In a context of transient simulation, the resulting models are economical because they do not require costly deformation-dependent integral evaluations. Furthermore, they can be used to establish analytical expressions of relevant physical quantities. This approach is validated with simulated and experimental data and compared qualitatively and quantitatively to other reduced-order modeling methods. hfill 2010-0128 |
| Author | Arndt, G Juillard, J Colinet, E |
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| Keywords | Transient response High strain modeling Micromachining microelectromechanical systems Experimental study Electrostatic devices Cantilever beam Galerkin-Petrov method nonlinear systems Squeeze film Casimir effect Modelling Reduced order systems Non linear effect Least square fit Microelectromechanical device |
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| References | appell (ref15) 1926 ref12 gupta (ref13) 1996 vemuri (ref16) 2000 leus (ref7) 2004 ref20 ref11 tilmans (ref14) 1994; 45 ref10 bao (ref9) 2000; 8 ref2 ref1 langlois (ref18) 1962; 20 ref19 ref8 ref4 ref3 ref6 ref5 veijola (ref17) 2001 |
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| SubjectTerms | Cantilever beams Computational efficiency Computer Science Computer simulation Damping Electrostatic devices Engineering Sciences Exact sciences and technology Exact solutions Force Instruments, apparatus, components and techniques common to several branches of physics and astronomy Inverse Least squares approximation Mathematical analysis Mathematical model Mathematical models Mathematics Mechanical instruments, equipment and techniques Micro and nanotechnologies microelectromechanical systems Microelectronics Micromechanical devices and systems Micromechanics modeling Modeling and Simulation nonlinear systems Numerical Analysis Physics Shape Structural beams Studies |
| Title | Modeling of Micromachined Beams Subject to Nonlinear Restoring or Damping Forces |
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