Capacitive Bio-Inspired Flow Sensing Cupula

Capacitive Bio-Inspired Flow Sensing Cupula

Submersible robotics have improved in efficiency and versatility by incorporating features found in aquatic life, ranging from thunniform kinematics to shark skin textures. To fully realize these benefits, sensor systems must be incorporated to aid in object detection and navigation through complex...

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Bibliographic Details
Main Authors: James P. Wissman, Kaushik Sampath, Simon E. Freeman, Charles A. Rohde
Format: Article
Language:English
Published: MDPI AG 2019-06-01
Series:Sensors
Subjects:
capacitive sensing
flow sensing
cupula
liquid metal
stretchable electronics
Online Access:https://www.mdpi.com/1424-8220/19/11/2639
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spelling doaj-7800468717da41d897c30a6dd6f082f22020-11-25T00:16:48ZengMDPI AGSensors1424-82202019-06-011911263910.3390/s19112639s19112639Capacitive Bio-Inspired Flow Sensing CupulaJames P. Wissman0Kaushik Sampath1Simon E. Freeman2Charles A. Rohde3U.S. Naval Research Laboratory, Code 7165, Washington, DC 20375, USAU.S. Naval Research Laboratory, Code 7165, Washington, DC 20375, USAU.S. Naval Undersea Warfare Center, Newport, RI 02841, USAU.S. Naval Research Laboratory, Code 7165, Washington, DC 20375, USASubmersible robotics have improved in efficiency and versatility by incorporating features found in aquatic life, ranging from thunniform kinematics to shark skin textures. To fully realize these benefits, sensor systems must be incorporated to aid in object detection and navigation through complex flows. Again, inspiration can be taken from biology, drawing on the lateral line sensor systems and neuromast structures found on fish. To maintain a truly soft-bodied robot, a man-made flow sensor must be developed that is entirely complaint, introducing no rigidity to the artificial “skin.” We present a capacitive cupula inspired by superficial neuromasts. Fabricated via lost wax methods and vacuum injection, our 5 mm tall device exhibits a sensitivity of 0.5 pF/mm (capacitance versus tip deflection) and consists of room temperature liquid metal plates embedded in a soft silicone body. In contrast to existing capacitive examples, our sensor incorporates the transducers into the cupula itself rather than at its base. We present a kinematic theory and energy-based approach to approximate capacitance versus flow, resulting in equations that are verified with a combination of experiments and COMSOL simulations.https://www.mdpi.com/1424-8220/19/11/2639capacitive sensingflow sensingcupulaliquid metalstretchable electronics
collection DOAJ
language English
format Article
sources DOAJ
author James P. Wissman
Kaushik Sampath
Simon E. Freeman
Charles A. Rohde
spellingShingle James P. Wissman
Kaushik Sampath
Simon E. Freeman
Charles A. Rohde
Capacitive Bio-Inspired Flow Sensing Cupula
Sensors
capacitive sensing
flow sensing
cupula
liquid metal
stretchable electronics
author_facet James P. Wissman
Kaushik Sampath
Simon E. Freeman
Charles A. Rohde
author_sort James P. Wissman
title Capacitive Bio-Inspired Flow Sensing Cupula
title_short Capacitive Bio-Inspired Flow Sensing Cupula
title_full Capacitive Bio-Inspired Flow Sensing Cupula
title_fullStr Capacitive Bio-Inspired Flow Sensing Cupula
title_full_unstemmed Capacitive Bio-Inspired Flow Sensing Cupula
title_sort capacitive bio-inspired flow sensing cupula
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2019-06-01
description Submersible robotics have improved in efficiency and versatility by incorporating features found in aquatic life, ranging from thunniform kinematics to shark skin textures. To fully realize these benefits, sensor systems must be incorporated to aid in object detection and navigation through complex flows. Again, inspiration can be taken from biology, drawing on the lateral line sensor systems and neuromast structures found on fish. To maintain a truly soft-bodied robot, a man-made flow sensor must be developed that is entirely complaint, introducing no rigidity to the artificial “skin.” We present a capacitive cupula inspired by superficial neuromasts. Fabricated via lost wax methods and vacuum injection, our 5 mm tall device exhibits a sensitivity of 0.5 pF/mm (capacitance versus tip deflection) and consists of room temperature liquid metal plates embedded in a soft silicone body. In contrast to existing capacitive examples, our sensor incorporates the transducers into the cupula itself rather than at its base. We present a kinematic theory and energy-based approach to approximate capacitance versus flow, resulting in equations that are verified with a combination of experiments and COMSOL simulations.
topic capacitive sensing
flow sensing
cupula
liquid metal
stretchable electronics
url https://www.mdpi.com/1424-8220/19/11/2639
work_keys_str_mv AT jamespwissman capacitivebioinspiredflowsensingcupula
AT kaushiksampath capacitivebioinspiredflowsensingcupula
AT simonefreeman capacitivebioinspiredflowsensingcupula
AT charlesarohde capacitivebioinspiredflowsensingcupula
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