Highly sensitive and low-crosstalk angular acceleration sensor using mirror-symmetric liquid ring channels and MEMS piezoresistive cantilevers

Highly sensitive and low-crosstalk angular acceleration sensor using mirror-symmetric liquid ring channels and MEMS piezoresistive cantilevers

[Display omitted] •Mirror-symmetric liquid ring channels lead to highly sensitive and low-crosstalk angular acceleration detection.•For the highly sensitive sensing element, a MEMS submicron-thick piezoresistive cantilever is utilized.•The differential pressure due to angular acceleration that is ap...

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Veröffentlicht in:Sensors and actuators. A. Physical. 2019-03, Vol.287, p.39-47
Hauptverfasser: Takahashi, Hidetoshi, Kan, Tetsuo, Nakai, Akihito, Takahata, Tomoyuki, Usami, Takanori, Shimoyama, Isao
Format: Artikel
Sprache:eng
Schlagworte:
Angular acceleration
Angular acceleration sensor
Axes (reference lines)
Channels
Crosstalk
Detection
Microelectromechanical systems
Piezoresistive cantilever
Power consumption
Ring flow channel
Rings (mathematics)
Rotating fluids
Sensitivity
Sensitivity analysis
Sensors
Symmetry
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container_end_page 47
container_issue
container_start_page 39
container_title Sensors and actuators. A. Physical.
container_volume 287
creator Takahashi, Hidetoshi
Kan, Tetsuo
Nakai, Akihito
Takahata, Tomoyuki
Usami, Takanori
Shimoyama, Isao
description [Display omitted] •Mirror-symmetric liquid ring channels lead to highly sensitive and low-crosstalk angular acceleration detection.•For the highly sensitive sensing element, a MEMS submicron-thick piezoresistive cantilever is utilized.•The differential pressure due to angular acceleration that is applied to the cantilever is in accordance with our calculated equations. This paper describes an angular acceleration sensor that uses liquid ring channels and piezoresistive cantilevers. The detection of fluidic rotation has attracted attention as a sensing principle for angular acceleration due to the simple structure and potentially low power consumption of devices that use said principle. Although the existing angular acceleration sensors that use this sensing principle have the potential for high sensitivity to angular acceleration about the target axis, crosstalk is an issue—specifically, crosstalk with angular accelerations about other axes and with linear acceleration. Here, we propose an angular acceleration sensor that uses a MEMS piezoresistive cantilever as the sensing element and two mirror-symmetric ring channels. This mirror symmetry cancels out the signals due to accelerations about the other axes, while the signal for the angular acceleration about the target axis is doubled. The experimental results show that the sensitivity to other axial angular accelerations and linear acceleration is sufficiently small. The obtained sensitivity for the angular acceleration is as high as 3.1 × 10−4 (rad/s2)-1, similar to theoretical predictions. This value for the sensitivity is maintained over a range of frequencies from 0.1 Hz to 100 Hz. Therefore, the proposed sensor is suitable for practical angular acceleration detection applications.
doi_str_mv 10.1016/j.sna.2019.01.006
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This paper describes an angular acceleration sensor that uses liquid ring channels and piezoresistive cantilevers. The detection of fluidic rotation has attracted attention as a sensing principle for angular acceleration due to the simple structure and potentially low power consumption of devices that use said principle. Although the existing angular acceleration sensors that use this sensing principle have the potential for high sensitivity to angular acceleration about the target axis, crosstalk is an issue—specifically, crosstalk with angular accelerations about other axes and with linear acceleration. Here, we propose an angular acceleration sensor that uses a MEMS piezoresistive cantilever as the sensing element and two mirror-symmetric ring channels. This mirror symmetry cancels out the signals due to accelerations about the other axes, while the signal for the angular acceleration about the target axis is doubled. The experimental results show that the sensitivity to other axial angular accelerations and linear acceleration is sufficiently small. The obtained sensitivity for the angular acceleration is as high as 3.1 × 10−4 (rad/s2)-1, similar to theoretical predictions. This value for the sensitivity is maintained over a range of frequencies from 0.1 Hz to 100 Hz. 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A. Physical.</title><description>[Display omitted] •Mirror-symmetric liquid ring channels lead to highly sensitive and low-crosstalk angular acceleration detection.•For the highly sensitive sensing element, a MEMS submicron-thick piezoresistive cantilever is utilized.•The differential pressure due to angular acceleration that is applied to the cantilever is in accordance with our calculated equations. This paper describes an angular acceleration sensor that uses liquid ring channels and piezoresistive cantilevers. The detection of fluidic rotation has attracted attention as a sensing principle for angular acceleration due to the simple structure and potentially low power consumption of devices that use said principle. Although the existing angular acceleration sensors that use this sensing principle have the potential for high sensitivity to angular acceleration about the target axis, crosstalk is an issue—specifically, crosstalk with angular accelerations about other axes and with linear acceleration. Here, we propose an angular acceleration sensor that uses a MEMS piezoresistive cantilever as the sensing element and two mirror-symmetric ring channels. This mirror symmetry cancels out the signals due to accelerations about the other axes, while the signal for the angular acceleration about the target axis is doubled. The experimental results show that the sensitivity to other axial angular accelerations and linear acceleration is sufficiently small. The obtained sensitivity for the angular acceleration is as high as 3.1 × 10−4 (rad/s2)-1, similar to theoretical predictions. This value for the sensitivity is maintained over a range of frequencies from 0.1 Hz to 100 Hz. 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A. Physical.</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Takahashi, Hidetoshi</au><au>Kan, Tetsuo</au><au>Nakai, Akihito</au><au>Takahata, Tomoyuki</au><au>Usami, Takanori</au><au>Shimoyama, Isao</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Highly sensitive and low-crosstalk angular acceleration sensor using mirror-symmetric liquid ring channels and MEMS piezoresistive cantilevers</atitle><jtitle>Sensors and actuators. A. Physical.</jtitle><date>2019-03-01</date><risdate>2019</risdate><volume>287</volume><spage>39</spage><epage>47</epage><pages>39-47</pages><issn>0924-4247</issn><eissn>1873-3069</eissn><abstract>[Display omitted] •Mirror-symmetric liquid ring channels lead to highly sensitive and low-crosstalk angular acceleration detection.•For the highly sensitive sensing element, a MEMS submicron-thick piezoresistive cantilever is utilized.•The differential pressure due to angular acceleration that is applied to the cantilever is in accordance with our calculated equations. This paper describes an angular acceleration sensor that uses liquid ring channels and piezoresistive cantilevers. The detection of fluidic rotation has attracted attention as a sensing principle for angular acceleration due to the simple structure and potentially low power consumption of devices that use said principle. Although the existing angular acceleration sensors that use this sensing principle have the potential for high sensitivity to angular acceleration about the target axis, crosstalk is an issue—specifically, crosstalk with angular accelerations about other axes and with linear acceleration. Here, we propose an angular acceleration sensor that uses a MEMS piezoresistive cantilever as the sensing element and two mirror-symmetric ring channels. This mirror symmetry cancels out the signals due to accelerations about the other axes, while the signal for the angular acceleration about the target axis is doubled. The experimental results show that the sensitivity to other axial angular accelerations and linear acceleration is sufficiently small. The obtained sensitivity for the angular acceleration is as high as 3.1 × 10−4 (rad/s2)-1, similar to theoretical predictions. This value for the sensitivity is maintained over a range of frequencies from 0.1 Hz to 100 Hz. 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subjects Angular acceleration
Angular acceleration sensor
Axes (reference lines)
Channels
Crosstalk
Detection
Microelectromechanical systems
Piezoresistive cantilever
Power consumption
Ring flow channel
Rings (mathematics)
Rotating fluids
Sensitivity
Sensitivity analysis
Sensors
Symmetry
title Highly sensitive and low-crosstalk angular acceleration sensor using mirror-symmetric liquid ring channels and MEMS piezoresistive cantilevers
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