Micromachined Accelerometers With Optical Interferometric Read-Out and Integrated Electrostatic Actuation

A micromachined accelerometer device structure with diffraction-based optical detection and integrated electrostatic actuation is introduced. The sensor consists of a bulk silicon proof mass electrode that moves vertically with respect to a rigid diffraction grating backplate electrode to provide in...

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Bibliographic Details
Published in:Journal of microelectromechanical systems 2008-02, Vol.17 (1), p.37-44
Main Authors: Hall, N.A., Okandan, M., Littrell, R., Serkland, D.K., Keeler, G.A., Peterson, K., Bicen, B., Garcia, C.T., Degertekin, F.L.
Format: Article
Language:English
Subjects:
Acceleration measurement
Accelerometers
Actuation
Arrays
Devices
diffraction
Dynamics
Electrodes
Electrostatic actuators
Electrostatics
Exact sciences and technology
feedback system
Instruments, apparatus, components and techniques common to several branches of physics and astronomy
Integrated optics
Lasers
Mechanical instruments, equipment and techniques
Micromechanical devices and systems
Optical devices
Optical diffraction
Optical interferometry
Optical sensors
Physics
Sensor arrays
Sensors
Vertical cavity surface emitting lasers
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Summary:A micromachined accelerometer device structure with diffraction-based optical detection and integrated electrostatic actuation is introduced. The sensor consists of a bulk silicon proof mass electrode that moves vertically with respect to a rigid diffraction grating backplate electrode to provide interferometric detection resolution of the proof-mass displacement when illuminated with coherent light. The sensor architecture includes a monolithically integrated electrostatic actuation port that enables the application of precisely controlled broadband forces to the proof mass while the displacement is simultaneously and independently measured optically. This enables several useful features such as dynamic self-characterization and a variety of force-feedback modalities, including alteration of device dynamics in situ. These features are experimentally demonstrated with sensors that have been optoelectronically integrated into sub-cubic-millimeter volumes using an entirely surface-normal, rigid, and robust embodiment incorporating vertical cavity surface emitting lasers and integrated photodetector arrays. In addition to small form factor and high acceleration resolution, the ability to self-characterize and alter device dynamics in situ may be advantageous. This allows periodic calibration and in situ matching of sensor dynamics among an array of accelerometers or seismometers configured in a network.
ISSN:1057-7157
1941-0158
DOI:10.1109/JMEMS.2007.910243