RF MEMS Oscillator with Integrated Resistive Transduction

Author

Reichenbach, R.B. ; Zalalutdinov, M. ; Parpia, J.M. ; Craighead, H.G.

Author_Institution

Dept. of Electr. & Comput. Eng., Cornell Univ., Ithaca, NY

Volume

27

Issue

10

fYear

2006

Firstpage

805

Lastpage

807

Abstract

A method to integrate micromechanical frequency-determining elements along with the corresponding electromechanical transducers into a poly or single-crystal silicon film layer is demonstrated. A resistor dissipating several microwatt of power induces high-frequency resonant mechanical motion in a shallow-shell membrane. Transduction from the mechanical to the electrical domain is performed using implanted piezoresistors, which are sensitive to strain produced by resonant motion. Self-sustained oscillations at 10 MHz are demonstrated when the device is directly coupled to a high-impedance operational amplifier and a positive feedback loop. Finally, this letter discuss how the resonator and transducers may be incorporated into standard integrated-circuit technology

Keywords

CMOS integrated circuits; circuit feedback; micromechanical resonators; operational amplifiers; piezoresistive devices; radiofrequency oscillators; transducers; 10 MHz; CMOS integrated circuits; MEMS oscillators; electromechanical transducers; integrated resistive transducers; operational amplifier; piezoresistors; positive feedback loop; resistance heating; Biomembranes; Frequency; Micromechanical devices; Oscillators; Radiofrequency microelectromechanical systems; Resistors; Resonance; Semiconductor films; Silicon; Transducers; CMOS integrated circuits; microelectromechanical devices; oscillators; resistance heating; resonators;

fLanguage

English

Journal_Title

Electron Device Letters, IEEE

Publisher

ieee

ISSN

0741-3106

Type

jour

DOI

10.1109/LED.2006.882526

Filename

1704906