Title :
A Vibration Resistant Nanopositioner for Mobile Parallel-Probe Storage Applications
Author :
Lantz, Mark A. ; Rothuizen, Hugo E. ; Drechsler, Ute ; Häberle, Walter ; Despont, Michel
Author_Institution :
IBM Zurich Res. Lab., Ruschlikon
Abstract :
We describe a planar microelectromechanical systems (MEMS)-based x/y nanopositioner designed for parallel-probe storage applications. The nanopositioner is actuated electromagnetically and has x/y motion capabilities of plusmn60 mum. The mechanical components are fabricated from a single-crystal silicon wafer using a deep-trench-etching process. To render the system robust against vibration, we utilize a mass-balancing concept that makes the system stiff against linear shock, but still compliant for actuation, and therefore results in low power consumption. We present details of the finite-element model used to design the device as well as experimental results for the frequency response, actuation, and vibration-rejection properties of the nanopositioner
Keywords :
finite element analysis; micromechanical devices; nanopositioning; sputter etching; wafer-scale integration; deep-trench-etching; finite-element model; low power consumption; mechanical components; mobile parallel-probe storage; planar microelectromechanical systems; single-crystal silicon wafer; vibration resistant nanopositioner; vibration-rejection properties; Electric shock; Energy consumption; Finite element methods; Microelectromechanical systems; Nanopositioning; Power system modeling; Robustness; Semiconductor device modeling; Silicon; Vibrations; Actuators; atomic force microscopy; microelectromechanical devices; motion control; motors;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2006.886032
