Modal analysis and modeling of a frictionless electrostatic rotary stepper micromotor

We present the design, modeling and characterization of a 3-phase electrostatic rotary stepper micromotor. The proposed motor is a monolithic device fabricated using silicon-on-insulator (SOI) technology. The rotor is suspended with a frictionless flexural pivot bearing and reaches an unprecedented rotational range of 30° (+/- 15°) at 65 V. We have established a mechanical model of the deformation structure and performed finite element analysis (FEA) simulations of the dynamic properties. These studies are consistent with the extensive experimental characterization performed in the quasi-static, transient, and dynamic regimes.

Modal analysis and modeling of a frictionless electrostatic rotary stepper micromotor

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Towards Scalable Electronics: Synthetic 2D Materials for Large-Area 2D Circuit Integration

Lithium tantalate photonic integrated circuits for volume manufacturing

Short-term behavior of glass fiber-polymer composite bending-active elastica beam under service load application

Towards Scalable Electronics: Synthetic 2D Materials for Large-Area 2D Circuit Integration

Lithium tantalate photonic integrated circuits for volume manufacturing

Short-term behavior of glass fiber-polymer composite bending-active elastica beam under service load application