Title :
Microcavity interferometry for MEMS device characterization
Author :
Stievater, Todd H. ; Rabinovich, William S. ; Newman, Harvey S. ; Ebel, Jack L. ; Mahon, Rita ; McGee, David J. ; Goetz, Peter G.
Author_Institution :
Naval Res. Lab., Washington, DC, USA
fDate :
2/1/2003 12:00:00 AM
Abstract :
We have developed a high resolution optical technique to measure the electromechanical properties of MEMS microstructures. The technique is applied to microbridges developed for capacitive switching in coplanar radio frequency (RF) waveguides. The thin metal ground plane on the substrate and the bottom of the bridge together form a microcavity for an optical beam. The wavelength of a cavity mode is a sensitive measure of the bridge position relative to the substrate. The technique is applied to the measurement of resonances and damping times of microbridges of varying lengths. It is also used to measure dc changes in bridge height of tenths of nanometers, driven ac displacements of less than a picometer, and bridge displacement noise of hundreds of femtometers per root Hertz. This extreme sensitivity exceeds previously demonstrated optical characterization methods.
Keywords :
UHF devices; coplanar waveguides; damping; light interference; light interferometry; micromechanical devices; microwave limiters; MEMS; capacitive switching; coplanar radio frequency waveguides; damping times; device characterization; electromechanical properties; microbridges; microcavity interferometry; optical characterization methods; resonances; thin metal ground plane; Bridge circuits; Microcavities; Microelectromechanical devices; Optical interferometry; Optical noise; Optical sensors; Optical waveguides; Radio frequency; Ultrafast optics; Wavelength measurement;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2002.807465
