H.K. Lee scite author profile

Micromechanical resonators (MEMS resonators) often show a discrepancy between the frequencytemperature (f-T) characteristics they have in open-loop and closed-loop measurements. We show that this discrepancy is due to the nonlinear amplitude-frequency (A-f) effect: the quality factor (Q) can increase by more than a factor of 2 when the resonators go from a high temperature to a low temperature; simple oscillators thus allow the resonator amplitude to change with temperature; then, the A-f effect becomes temperaturedependent, causing the discrepancy. We also show how the discrepancy adversely affects the temperature stability of single-crystal-silicon (SCS) resonators and demonstrate a new closed-loop system that improves the stability by removing the discrepancy.

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H.K. Lee

Verification of the phase-noise model for MEMS oscillators operating in the nonlinear regime

Exploring the limits and practicality of Q-based temperature compensation for silicon resonators

Phase Lock Loop based Temperature Compensation for MEMS Oscillators

A High-Stability MEMS Frequency Reference

Influence of the A-F effect on the temperature stability of silicon micromechanical resonators

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