Integrated force and displacement sensing in an untethered dielectric elastomer actuator with a piezoresistive element
Integrated force and displacement sensing in an untethered dielectric elastomer actuator with a piezoresistive element
Dielectric elastomer actuators, owing to their fully electrical control and silent operation, are becoming increasingly popular for the development of terrestrial and underwater mobile robots with versatile locomotion capabilities. It is essential to embed the ability to sense their state and external interactions in these robots to facilitate the development of future autonomous capabilities. However, sensorizing dielectric elastomer actuators for untethered robotic applications is challenging due to their use of high voltage and the nonlinear mechanics of the elastomers utilized in them. To address this challenge, we developed a novel technique based on embedded piezoresistive sensing and high voltage feedback to simultaneously estimate the actuator displacement and external force in a fully untethered actuator driven by a miniature low-cost voltage amplifier. A data-driven regression model has been developed to accurately estimate force and displacement from the measured data. Validation tests conducted on three actuators demonstrate promising results. We achieve RMSE values as low as 29.736 mN for force estimation and 0.023 mm for displacement estimation in the zero-voltage condition, where the actuator is subjected to a triangular wave with a mechanical frequency of 0.1 Hz and an amplitude of 3 mm. Additionally, we have realized fully untethered operation by employing a power source, small-size voltage amplifier, microcontroller, and wireless connectivity module embedded in a compact form-factor. This work presents a significant advancement in soft robotics, offering a reliable and cost-effective solution for future autonomous robotic systems based on high-voltage dielectric elastomer actuators.
Saha, Dip Kumar
45bef093-bf72-411b-8452-6eeda3ae7d68
Godaba, Hareesh
787c1482-6a29-43ad-b49e-a6a2b7175f0c
8 December 2023
Saha, Dip Kumar
45bef093-bf72-411b-8452-6eeda3ae7d68
Godaba, Hareesh
787c1482-6a29-43ad-b49e-a6a2b7175f0c
Saha, Dip Kumar and Godaba, Hareesh
(2023)
Integrated force and displacement sensing in an untethered dielectric elastomer actuator with a piezoresistive element.
Sensors and Actuators, A: Physical, 365, [114889].
(doi:10.1016/j.sna.2023.114889).
Abstract
Dielectric elastomer actuators, owing to their fully electrical control and silent operation, are becoming increasingly popular for the development of terrestrial and underwater mobile robots with versatile locomotion capabilities. It is essential to embed the ability to sense their state and external interactions in these robots to facilitate the development of future autonomous capabilities. However, sensorizing dielectric elastomer actuators for untethered robotic applications is challenging due to their use of high voltage and the nonlinear mechanics of the elastomers utilized in them. To address this challenge, we developed a novel technique based on embedded piezoresistive sensing and high voltage feedback to simultaneously estimate the actuator displacement and external force in a fully untethered actuator driven by a miniature low-cost voltage amplifier. A data-driven regression model has been developed to accurately estimate force and displacement from the measured data. Validation tests conducted on three actuators demonstrate promising results. We achieve RMSE values as low as 29.736 mN for force estimation and 0.023 mm for displacement estimation in the zero-voltage condition, where the actuator is subjected to a triangular wave with a mechanical frequency of 0.1 Hz and an amplitude of 3 mm. Additionally, we have realized fully untethered operation by employing a power source, small-size voltage amplifier, microcontroller, and wireless connectivity module embedded in a compact form-factor. This work presents a significant advancement in soft robotics, offering a reliable and cost-effective solution for future autonomous robotic systems based on high-voltage dielectric elastomer actuators.
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Accepted/In Press date: 28 November 2023
e-pub ahead of print date: 30 November 2023
Published date: 8 December 2023
Identifiers
Local EPrints ID: 499674
URI: http://eprints.soton.ac.uk/id/eprint/499674
ISSN: 0924-4247
PURE UUID: 804c1f0f-eeaa-4f42-be02-8f9e8ddb01f3
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Date deposited: 31 Mar 2025 16:40
Last modified: 22 Aug 2025 02:46
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Author:
Dip Kumar Saha
Author:
Hareesh Godaba
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