Title :
Mode-Localized Displacement Sensing
Author :
Thiruvenkatanathan, P. ; Seshia, A.A.
Author_Institution :
Dept. of Eng., Univ. of Cambridge, Cambridge, UK
Abstract :
We report the construction of a new class of micromachined displacement sensors that employ the phenomenon of vibration-mode localization for monitoring minute inertial displacements. It is demonstrated both theoretically and experimentally that the eigenstate-shifted output signal of such mode-localized displacement sensors may be as high as 1000 times greater than corresponding resonant-frequency variations that serve as the output in the more traditional vibratory resonant micromechanical displacement/motion sensors. The high parametric sensitivities attainable in such mode-localized displacement sensors, together with their inherent advantages of improved environmental robustness and electrical tunability, suggest an alternative approach in achieving improved sensitivity and stability in high-resolution displacement transduction.
Keywords :
circuit resonance; displacement measurement; eigenvalues and eigenfunctions; microsensors; sensitivity analysis; vibrational modes; eigenstate-shifted output signal; electrical tunability; environmental robustness; high-resolution displacement transduction; micromachined displacement sensor; minute inertial displacement monitoring; mode-localized displacement sensing; mode-localized displacement sensor; parametric sensitivity; resonant-frequency variation; stability; vibration-mode localization; vibratory resonant micromechanical displacement/motion sensor; Couplings; Displacement measurement; Optical resonators; Resonant frequency; Sensitivity; Sensors; Vibrations; Microelectromechanical resonators; mode localization; mode-localized sensing;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2012.2198047
