Fiber temperature sensor utilizing a thermomechanical MEMS detector

Huseyin Cirkinoglu; Habib Bilgin; Fehmi Civitci; Hamdi Torun; Onur Ferhanoglu

doi:10.1109/JLT.2015.2502992

Fiber temperature sensor utilizing a thermomechanical MEMS detector

Huseyin Cirkinoglu, Habib Bilgin, Fehmi Civitci, Hamdi Torun, Onur Ferhanoglu

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

We propose a novel fiber sensor utilizing a thermomechanical MEMS element at the fiber tip. Owing to its Parylene/Titanium bimaterial structure, the MEMS membrane exhibits an out-of-plane displacement with changing temperature. Together with the MEMS element, the embedded diffraction grating forms an in-line interferometer, from which the displacement as well as the temperature can be deduced. The fabricated detector is placed at the single-mode fiber output that is collimated via a graded index lens. This novel architecture allows for integrating MEMS detectors on standard optical fibers, and easy substitution of the MEMS detector element to alter the measurement range and the response time of the sensor. Temperature and time-constant measurements are provided and verified with reference measurements, revealing a temperature sensitivity better than 20 mK and 2.5-ms response time, using low-cost laser source and photodetectors.

Original language	English
Pages (from-to)	1025-1030
Journal	Journal of Lightwave Technology
Volume	34
Issue number	3
DOIs	https://doi.org/10.1109/JLT.2015.2502992
Publication status	Published - 5 Feb 2016

Keywords

microelectomechanical devices
optical device fabrication
temperature measurement

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10.1109/JLT.2015.2502992

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title = "Fiber temperature sensor utilizing a thermomechanical MEMS detector",

abstract = "We propose a novel fiber sensor utilizing a thermomechanical MEMS element at the fiber tip. Owing to its Parylene/Titanium bimaterial structure, the MEMS membrane exhibits an out-of-plane displacement with changing temperature. Together with the MEMS element, the embedded diffraction grating forms an in-line interferometer, from which the displacement as well as the temperature can be deduced. The fabricated detector is placed at the single-mode fiber output that is collimated via a graded index lens. This novel architecture allows for integrating MEMS detectors on standard optical fibers, and easy substitution of the MEMS detector element to alter the measurement range and the response time of the sensor. Temperature and time-constant measurements are provided and verified with reference measurements, revealing a temperature sensitivity better than 20 mK and 2.5-ms response time, using low-cost laser source and photodetectors.",

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AU - Cirkinoglu, Huseyin

AU - Bilgin, Habib

AU - Civitci, Fehmi

AU - Torun, Hamdi

AU - Ferhanoglu, Onur

PY - 2016/2/5

Y1 - 2016/2/5

N2 - We propose a novel fiber sensor utilizing a thermomechanical MEMS element at the fiber tip. Owing to its Parylene/Titanium bimaterial structure, the MEMS membrane exhibits an out-of-plane displacement with changing temperature. Together with the MEMS element, the embedded diffraction grating forms an in-line interferometer, from which the displacement as well as the temperature can be deduced. The fabricated detector is placed at the single-mode fiber output that is collimated via a graded index lens. This novel architecture allows for integrating MEMS detectors on standard optical fibers, and easy substitution of the MEMS detector element to alter the measurement range and the response time of the sensor. Temperature and time-constant measurements are provided and verified with reference measurements, revealing a temperature sensitivity better than 20 mK and 2.5-ms response time, using low-cost laser source and photodetectors.

AB - We propose a novel fiber sensor utilizing a thermomechanical MEMS element at the fiber tip. Owing to its Parylene/Titanium bimaterial structure, the MEMS membrane exhibits an out-of-plane displacement with changing temperature. Together with the MEMS element, the embedded diffraction grating forms an in-line interferometer, from which the displacement as well as the temperature can be deduced. The fabricated detector is placed at the single-mode fiber output that is collimated via a graded index lens. This novel architecture allows for integrating MEMS detectors on standard optical fibers, and easy substitution of the MEMS detector element to alter the measurement range and the response time of the sensor. Temperature and time-constant measurements are provided and verified with reference measurements, revealing a temperature sensitivity better than 20 mK and 2.5-ms response time, using low-cost laser source and photodetectors.

KW - microelectomechanical devices

KW - optical device fabrication

KW - temperature measurement

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DO - 10.1109/JLT.2015.2502992

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JO - Journal of Lightwave Technology

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Fiber temperature sensor utilizing a thermomechanical MEMS detector

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Keywords

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