Soft multi-point waveguide sensor for proprioception and extereoception in inflatable fingers
Soft multi-point waveguide sensor for proprioception and extereoception in inflatable fingers
Disadvantages of conventional robotic systems include rigidity, multiple moving parts, and the need for elaborate safety mechanisms when used in human-machine interaction. Soft manipulators and grippers are gaining in popularity due to being able to handle large payloads whilst being lightweight, highly compliant, low-cost, and compactible or collapsible. Yet soft robots cannot make use of traditional rigid sensors to measure their pose or interaction with the environment. Perception in soft robotics needs to embrace alternative methods: sensors made from soft materials that perform robustly under compression and bending conditions; i.e, stretchable soft sensors that rely on (their) material and electrical properties to output signal measurements. However, many such sensors come with inherent drawbacks, including material incompatibility, fabrication complexity, and hysteresis. In this paper, we report on the use of multiple staggered optical waveguide sensors embedded in silicone. These stretchable optical waveguide sensors coated with a thin layer of gold were fabricated and integrated with a fabric-based, inflatable robot finger. An experimental study was performed to evaluate the sensor's responsiveness. We find that multi-curvature pose estimation (from 0.05-0.135 m-1) (from fully deflated to maximum inflation) can be acquired after integration with the inflatable robot finger. The sensor proves capable of measuring force information by way of interaction with the environment at multiple points along the gripper.
574-579
Hassan, Ahmed
74e8ea6a-6830-4cf0-b38a-3a4e8d972e39
Aljaber, Faisal
02d44892-1e72-4125-8278-7837fee3c8e7
Godaba, Hareesh
787c1482-6a29-43ad-b49e-a6a2b7175f0c
Vitanov, Ivan
9ddcc734-15bf-4aeb-8fbf-ce06cd2524ab
Althoefer, Kaspar
031c800b-bf48-4996-8c17-29f7408898c6
15 November 2021
Hassan, Ahmed
74e8ea6a-6830-4cf0-b38a-3a4e8d972e39
Aljaber, Faisal
02d44892-1e72-4125-8278-7837fee3c8e7
Godaba, Hareesh
787c1482-6a29-43ad-b49e-a6a2b7175f0c
Vitanov, Ivan
9ddcc734-15bf-4aeb-8fbf-ce06cd2524ab
Althoefer, Kaspar
031c800b-bf48-4996-8c17-29f7408898c6
Hassan, Ahmed, Aljaber, Faisal, Godaba, Hareesh, Vitanov, Ivan and Althoefer, Kaspar
(2021)
Soft multi-point waveguide sensor for proprioception and extereoception in inflatable fingers.
In 6th International Forum on Research and Technology for Society and Industry, RTSI 2021 - Proceedings.
IEEE.
.
(doi:10.1109/RTSI50628.2021.9597247).
Record type:
Conference or Workshop Item
(Paper)
Abstract
Disadvantages of conventional robotic systems include rigidity, multiple moving parts, and the need for elaborate safety mechanisms when used in human-machine interaction. Soft manipulators and grippers are gaining in popularity due to being able to handle large payloads whilst being lightweight, highly compliant, low-cost, and compactible or collapsible. Yet soft robots cannot make use of traditional rigid sensors to measure their pose or interaction with the environment. Perception in soft robotics needs to embrace alternative methods: sensors made from soft materials that perform robustly under compression and bending conditions; i.e, stretchable soft sensors that rely on (their) material and electrical properties to output signal measurements. However, many such sensors come with inherent drawbacks, including material incompatibility, fabrication complexity, and hysteresis. In this paper, we report on the use of multiple staggered optical waveguide sensors embedded in silicone. These stretchable optical waveguide sensors coated with a thin layer of gold were fabricated and integrated with a fabric-based, inflatable robot finger. An experimental study was performed to evaluate the sensor's responsiveness. We find that multi-curvature pose estimation (from 0.05-0.135 m-1) (from fully deflated to maximum inflation) can be acquired after integration with the inflatable robot finger. The sensor proves capable of measuring force information by way of interaction with the environment at multiple points along the gripper.
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Published date: 15 November 2021
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Local EPrints ID: 499174
URI: http://eprints.soton.ac.uk/id/eprint/499174
PURE UUID: a48d3ce6-4c22-437d-8d49-19f5c94f3c43
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Date deposited: 11 Mar 2025 17:35
Last modified: 12 Mar 2025 03:15
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Author:
Ahmed Hassan
Author:
Faisal Aljaber
Author:
Hareesh Godaba
Author:
Ivan Vitanov
Author:
Kaspar Althoefer
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