Your search keyword '"Zehnder, Alan T."' showing total 5 results

1. Modeling of Coupled Dome-Shaped Microoscillators.

Author

Sahai, Tuhin and Zehnder, Alan T.

Subjects

*MICROMECHANICS, *ELECTRIC oscillators, *SIGNAL processing, *SILICON, *DIFFERENTIAL equations, *HEAT equation

Abstract

Synchronized micromechanical oscillators have potential for applications in signal processing, neural computing, sensing, and other fields. This paper explores the conditions under which coupled nonlinear limit cycle microoscillators can synchronize. As an example of the modeling approach and to be able to obtain results for a system that has been experimentally realized, thermally excited dome oscillators, which are fabricated by buckling of a thin circular film of polysilicon, are modeled. Starting with the von Kármán plate equations and an assumed mode shape, a Galerkin projection is performed to obtain an ordinary differential equation for the postbuckled dynamics of the mode. Because the structure is thermally excited, a thermal model is built by solving the heat equation on a disk with appropriate boundary conditions. Bifurcation analysis of the single oscillator model is performed to look for basic underlying phenomena. Conditions under which two slightly detuned coupled limit cycle dome oscillators will synchronize are explored. [ABSTRACT FROM AUTHOR]

Published

2008

2. Analysis of Frequency Locking in Optically Driven MEMS Resonators.

Author

Pandey, Manoj, Aubin, Keith, Zalalutdinov, Maxim, Reichenbach, Robert B., Zehnder, Alan T., Rand, Richard H., and Craighead, Harold G.

Subjects

RESONATORS, RADIO frequency, MICROELECTROMECHANICAL systems, PIEZOELECTRICITY, ELECTROMECHANICAL devices, MECHATRONICS

Abstract

Thin, planar, radio frequency microelectromechanical systems (MEMS) resonators have been shown to self-oscillate in the absence of external forcing when illuminated by a direct current (dc) laser of sufficient amplitude. In the presence of external forcing of sufficient strength and close enough in frequency to that of the unforced oscillation, the device will become frequency locked, or entrained, by the forcing. In other words, it will vibrate at the frequency of the external forcing. Experimental results demonstrating entrainment for a disk-shaped oscillator under optical and mechanical excitation are reviewed. A thermomechanical model of the system is developed and its predictions explored to explain and predict the entrainment phenomenon. The validity of the model is demonstrated by the good agreement between the predicted and experimental results. The model equations could also be used to analyze MEMS limit-cycle oscillators designed to achieve specific performance objectives. [ABSTRACT FROM AUTHOR]

Published

2006

3. Shell-type micromechanical actuator and resonator.

Author

Zalalutdinov, Maxim, Aubin, Keith L., Reichenbach, Robert B., Zehnder, Alan T., Houston, Brian, Parpia, Jeevak M., and Craighead, Harold G.

Subjects

MICROELECTROMECHANICAL systems, ACTUATORS, RESONATORS, RADIO frequency, MICROMECHANICS

Abstract

Dome-shaped radio-frequency micromechanical resonators were fabricated by utilizing the buckling of a prestressed thin polysilicon film. The enhanced rigidity of the dome structure leads to a significant increase of its resonant frequency compared to a flat plate resonator. The shell-type geometry of the structure also provides an imbedded actuation mechanism. Significant out-of plane deflections are actuated by mechanical stress introduced within the plane of the shell. We demonstrate that thermomechanical stress generated by a focused laser beam, or microfabricated resistive heater, provides an effective and fast mechanism to operate the dome as an acoustic resonator in the radio-frequency range. All-optical operation of the shell resonator and an integrated approach are discussed. © 2003 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2003

4. Multiple limit cycles in laser interference transduced resonators

Author

Blocher, David, Rand, Richard H., and Zehnder, Alan T.

Subjects

*LASER interferometry, *RESONATORS, *LIMIT cycles, *LIGHT absorption, *NUMERICAL integration, *THERMAL stresses

Abstract

Abstract: Nanoscale resonators whose motion is measured through laser interferometry are known to exhibit stable limit cycle motion. Motion of the resonator through the interference field modulates the amount of light absorbed by the resonator and hence the temperature field within it. The resulting coupling of motion and thermal stresses can lead to self-oscillation, i.e. a limit cycle. In this work the coexistence of multiple stable limit cycles is demonstrated in an analytic model. Numerical continuation and direct numerical integration are used to study the structure of the solutions to the model. The effect of damping is discussed as well as the properties that would be necessary for physical devices to exhibit this behavior. [Copyright &y& Elsevier]

Published

2013

5. Nondegenerate Parametric Resonance in Large Ensembles of Coupled Micromechanical Cantilevers with Varying Natural Frequencies.

Author

Wallin, Christopher B., De Alba, Roberto, Westly, Daron, Holland, Glenn, Grutzik, Scott, Rand, Richard H., Zehnder, Alan T., Aksyuk, Vladimir A., Krylov, Slava, and Ilic, B. Robert

Subjects

*MICROCANTILEVERS, *MICROMECHANICS, *RESONATORS

Abstract

We investigate the collective dynamics and nondegenerate parametric resonance (NPR) of coplanar, interdigitated arrays of microcantilevers distinguished by their cantilevers having linearly expanding lengths and thus varying natural frequencies. Within a certain excitation frequency range, the resonators begin oscillating via NPR across the entire array consisting of 200 single-crystal silicon cantilevers. Tunable coupling generated from fringing electrostatic fields provides a mechanism to vary the scope of the NPR. Our experimental results are supported by a reduced-order model that reproduces the leading features of our data including the NPR band. The potential for tailoring the coupled response of suspended mechanical structures using NPR presents new possibilities in mass, force, and energy sensing applications, energy harvesting devices, and optomechanical systems. [ABSTRACT FROM AUTHOR]

Published

2018