Large-displacement modelling and simulation of micromechanical electrostatically driven resonators using the harmonic balance method

Nonlinearities in electrostatically driven micromechanical resonators are studied with circuit simulations. Models for the resonators are built of elementary electrical equivalent-circuit blocks constructed of nonlinear voltage-controlled current and charge sources. They are simulated with the harmo...

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Bibliographic Details
Main Authors: Veijola, T., Mattila, T., Jaakkola, O., Kiihamaki, J., Lamminmaki, T., Oja, A., Ruokonen, K., Seppa, H., Seppala, P., Tittonen, I.
Format: Conference Proceeding
Language:English
Subjects:
Capacitance
Capacitors
Circuit simulation
Damping
Displacement control
Micromechanical devices
Power harmonic filters
Springs
Transducers
Voltage control
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Summary:Nonlinearities in electrostatically driven micromechanical resonators are studied with circuit simulations. Models for the resonators are built of elementary electrical equivalent-circuit blocks constructed of nonlinear voltage-controlled current and charge sources. They are simulated with the harmonic balance method in the RF-simulation program APLAC. Spring softening effects due to the capacitive transducer and spring hardening effects due to the resonator's third order spring coefficient are demonstrated by simulations. For verification, a model for a micromachined high-Q beam resonator structure has been constructed, and its measured large-displacement frequency-domain transfer characteristics are successfully reproduced by model simulations.
ISSN:0149-645X
2576-7216
DOI:10.1109/MWSYM.2000.860894