Diagnosis of operational changes in microelectromechanical systems via fault detection

Rittenhouse, Scott A.

doi:10.33915/etd.1509

Cited by 3 publications

(1 citation statement)

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“…This would seem to indicate that the nonvolatile components are already in the Borofloat in the form of the oxides of Al, Na and K which may act as"seeds" for growth into larger structures. These "seeds" would not interfere with the optical characteristics of Borofloat due to their small size which appears to be on the order of tens of nanometers as seen inFigure 4 16.…”

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Diffractive optical lens design and fabrication for integrated monitoring of microelectromechanical lateral comb resonators

McCormick¹

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Analysis of fault characteristics and control of microelectromechanical systems (MEMS) is becoming increasingly important as these devices are incorporated into safety critical systems. Mechanically decoupled monitoring techniques are needed to ensure that accurate, low-noise positional information is gathered from these devices during operation. Optical monitoring has been shown by various groups to be capable of achieving this goal. However, Integrated Optical Monitoring (IOM) must be achieved in order to enable incorporation with the MEMS die in a single package for effective lifetime system monitoring. This research addresses the design, fabrication and testing of diffractive optical elements (DOEs) for achieving IOM.. DOEs for on and off-axis single and multiple beam generation are modeled based on a linear optical system model paraxial gaussian beam theory. The DOEs are generated using a MATLAB tool that was completed as part of this work to calculate the desired input wave, output wave, and transfer function. This data is then used to generate a phase lens profile with an etch depth that is dependent on the material that will be used for lens fabrication. DOEs are fabricated on a borosilicate substrate and testing of the lenses is performed using a beam profiler to determine the number, shape and power of the probe beams for comparison with the results from the simulated lenses. Experimental DOE test results compare well with those obtained from the modeling tool validating the use of the DOE design tool and the fabrication process for subsequent research implementing IOM architectures.

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Diffractive optical lens design and fabrication for integrated monitoring of microelectromechanical lateral comb resonators

McCormick¹

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Fault Detection Considerations in Silicon Based MEMS Resonators by Observing Changes in Dynamic Behaviour

İkizoğlu¹,

Akyol²

2014

Balkan Journal of Electrical and Computer Engineering

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Abstract-This study is about fault detection in siliconbased MEMS resonators. The main idea in finding out the failure is to establish a proper relationship between the mechanical structure and its electrical equivalent and prosecuting related measurements. In order to determine the type of defect, the electrical equivalent circuit is referenced considering the parasitic effects. Among various possible faults cracks in the beam and particle adhesion are selected to verify the validity of the approach. Simulations are carried out to study the effect of defects on the resonance frequency and amplitude. Results coincide greatly with those of similar investigations giving motivation for further studies to penetrate deep into the matter, thus not being restricted with defining the trouble, but even locate the failure.

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Design of Direct Exponential Observers for Fault Detection of Nonlinear MEMS Tunable Capacitor

Mobki

Sadeghi

Rezazadeh

2015

IJE

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Diagnosis of operational changes in microelectromechanical systems via fault detection

Cited by 3 publications

References 50 publications

Diffractive optical lens design and fabrication for integrated monitoring of microelectromechanical lateral comb resonators

Diffractive optical lens design and fabrication for integrated monitoring of microelectromechanical lateral comb resonators

Fault Detection Considerations in Silicon Based MEMS Resonators by Observing Changes in Dynamic Behaviour

Design of Direct Exponential Observers for Fault Detection of Nonlinear MEMS Tunable Capacitor

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