Accurate simulation of parametrically excited micromirrors via direct computation of the electrostatic stiffness

Abstract

Electrostatically actuated torsional micromirrors are key elements in Micro-Opto-Electro-Mechanical-Systems. When forced by means of in-plane comb-fingers, the dynamics of the main torsional response is known to be strongly non-linear and governed by parametric resonance. Here, in order to also trace unstable branches of the mirror response, we implement a simplified continuation method with arc-length control and propose an innovative technique based on Finite Elements and the concepts of material derivative in order to compute the electrostatic stiffness; i.e., the derivative of the torque with respect to the torsional angle, as required by the continuation approach.