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MEMS Resonator Simulation (RTH46/JD)

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MEMS Resonator Simulation (RTH46/JD) David S. Bindel, Emmanuel Quevy, Tsuyoshi Koyama Sanjay Govindjee, James W. Demmel, Roger T. Howe Introduction High-frequency ... – PowerPoint PPT presentation

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Title: MEMS Resonator Simulation (RTH46/JD)


1
MEMS Resonator Simulation(RTH46/JD)
  • David S. Bindel, Emmanuel Quevy, Tsuyoshi Koyama
  • Sanjay Govindjee, James W. Demmel, Roger T. Howe

2
Introduction
  • High-frequency surface-micromachined MEMS
    resonators have many applications
  • Filters, frequency references, sensors
  • Need high quality factors
  • Difficult to predict analytically
  • Existing tools predict frequency, but not Q
  • Anchor loss is a major damping source
  • Simulate anchor loss with perfectly matched
    layers
  • Illustrate anchor loss in disk resonators
  • Loss is surprisingly sensitive to geometry
    variations
  • Thermoelastic damping can also be significant

3
Loss Model of a Disk Resonator
Device micrographs (top) and schematic (bottom)
Device micrographs (top) and schematic (bottom)
4
Loss Model of a Disk Resonator
  • Simulated and built poly-SiGe disk resonators
  • 31.5 and 41.5 micron radii, 1.5 micron height
  • Post is 1.5 micron radius, 1 micron height
  • Fabricated dimensions vary from nominal

5
Basic Loss Mechanism
Displacement and mean energy flux at resonance
  • Dominant mode is not purely radial!

6
Basic Loss Mechanism
  • Dominant mode is not purely radial!
  • Includes a small bending motion
  • Vertical motion at post pumps elastic waves into
    substrate
  • More bending motion when radial and bending
    modes are close in frequency

7
Design Sensitivity
  • Simulated Q (solid line, left) very sensitive to
    film thickness
  • Matches experimental data (dots)
  • Sensitivity comes from interaction between two
    poles which come close at critical thicknesses
    (right)

8
Thermoelastic Damping
  • Compute thermoelastic interactions from coupled
    PDEs
  • Matches Zeners formula on a beam geometry
  • Works more generally than Zeners formula

9
TED and Grain Boundaries
  • Grain boundaries affect thermal conductivity and
    add another thermal length scale
  • Working to include grain boundary effects in our
    thermoelastic damping simulations

10
Conclusions
  • Need CAD tools to predict damping
  • Simulations of anchor losses using perfectly
    matched layers
  • Simulations of thermoelastic damping through
    coupled PDEs
  • Illustrated usefulness of our approach on a disk
    resonator
  • Both simulation and experiment show surprising
    dips in Q from interactions between modes
  • Poisson coupling is important acoustic
    approximations are inadequate to capture the
    behavior

11
References
  • http//www.cs.berkeley.edu/dbindel/hiqlab
  • Program code is freely available
  • Tutorial slides and relevant papers also
    available
  • Papers
  • Elastic PMLs for resonator anchor loss
    simulation. Tech report UCB/SEMM-2005/01.
    Submitted to IJNME.
  • Anchor Loss Simulation in Resonators. MEMS
    2005.
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