Periodic solutions and the avoidance of pull‐in instability in nonautonomous microelectromechanical systems
Copyright policy )Periodic solutions and the avoidance of pull‐in instability in nonautonomous microelectromechanical systems
We study periodic solutions of a one‐degree of freedom microelectromechanical system (MEMS) with a parallel‐plate capacitor under T‐periodic electrostatic forcing. We obtain analytical results concerning the existence of T‐periodic solutions of the problem in the case of arbitrary nonlinear restoring force, as well as when the moving plate is attached to a spring fabricated using graphene. We then demonstrate numerically on a T‐periodic Poincaré map of the flow that these solutions are generally locally stable with large “islands” of initial conditions around them, within which the pull‐in stability is completely avoided. We also demonstrate graphically on the Poincaré map that stable periodic solutions with higher period nT, n > 1 also exist, for wide parameter ranges, with large “islands” of bounded motion around them, within which all initial conditions avoid the pull‐in instability, thus helping us significantly increase the domain of safe operation of these MEMS models.
- Süleyman Şah University Turkey
- University of Patras Greece
- Suleyman Demirel University Kazakhstan
- Nazarbayev University Kazakhstan
periodic electrostatic forcing, Micromechanics of solids, Nonautonomous smooth dynamical systems, Nonlinear oscillations and coupled oscillators for ordinary differential equations, Dynamical Systems (math.DS), forced graphene oscillator, pull-in, Dynamical systems in solid mechanics, 515, Bifurcations of limit cycles and periodic orbits in dynamical systems, FOS: Mathematics, Mathematics - Dynamical Systems
periodic electrostatic forcing, Micromechanics of solids, Nonautonomous smooth dynamical systems, Nonlinear oscillations and coupled oscillators for ordinary differential equations, Dynamical Systems (math.DS), forced graphene oscillator, pull-in, Dynamical systems in solid mechanics, 515, Bifurcations of limit cycles and periodic orbits in dynamical systems, FOS: Mathematics, Mathematics - Dynamical Systems
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