Abstract
This study investigates the nonlinear dynamic response behavior of a rotating ring that forms an essential element of MEMS (Micro Electro Mechanical Systems) ring-based vibratory gyroscopes that utilize oscillatory nonlinear electrostatic forces. For this purpose, the dynamic behavior due to nonlinear system characteristics and nonlinear external forces was studied in detail. The partial differential equations that represent the ring dynamics are reduced to coupled nonlinear ordinary differential equations by suitable addition of nonlinear mode functions and application of Galerkin’s procedure. Understanding the effects of nonlinear actuator dynamics is essential for characterizing the dynamic behavior of such devices. For this purpose, a suitable theoretical model to generate a nonlinear electrostatic force acting on the MEMS ring structure is formulated. Nonlinear dynamic responses in the driving and sensing directions are examined via time response, phase diagram, and Poincare’s map when the input angular motion and nonlinear electrostatic force are considered simultaneously. The analysis is envisaged to aid ongoing research associated with the fabrication of this type of device and provide design improvements in MEMS ring-based gyroscopes.
Highlights
Vibratory angular rate sensors have received considerable attention in the recent past, primarily due to the economic and technological advantages offered by this class of sensors
The present study focuses on a nonlinear system and the interaction of nonlinear electrostatic forces to investigate the nonlinear dynamic response behavior
A comprehensive mathematical model representing the nonlinear dynamic for use in vibratory angular rate sensors
Summary
Vibratory angular rate sensors have received considerable attention in the recent past, primarily due to the economic and technological advantages offered by this class of sensors. The dynamic response behavior of rotating thin circular rings for use in vibratory angular rate sensors was investigated by Gebrel et al [12] via numerical simulations by employing a linearized model considering the second mode. The dynamic behavior of rotating MEMS-based vibratory gyroscopes via numerical simulations by considering a linearized model subjected to a nonlinear actuator was performed by Gebrel et al [14]. Theoretical and experimental studies on the linear and nonlinear dynamics of MEMS/NEMS (Nano Electro Mechanical Systems) and their exploitation for various applications have been investigated in detail [23,24,25] Another important research has been performed on nonlinear microsystems, such as reduced-order modeling and gyroscopes [26,27,28]. The phase diagram and Poincare maps were obtained via numerical simulation for linear and nonlinear systems, in particular, to gain insight into the inherent nonlinear behavior
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