Multi-Axis Force/Torque Sensor Based on Simply-Supported Beam and Optoelectronics

Noh, Yohan; Bimbo, João; Sareh, Sina; Würdemann, Helge A.; Fraś, Jan; Chathuranga, Damith Suresh; Liu, Hongbin; Housden, James; Althoefer, Kaspar; Rhode, Kawal

doi:10.3390/s16111936

Cited by 46 publications

(26 citation statements)

References 42 publications

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“…Despite all of the remarkable progress in the development for the flexible manipulators, sensing modalities which recognise physical conditions in the body and/or which detects the manipulator's shape and posture have not been fully realised. Whereas legacy manipulators provide their location information to some extent, they do not feedback information about touch and precise force exertion, which are critical for protecting vital organs against potential damages [19][20].…”

Section: A Contact Force Sensor Based On S-shaped Beams and Optoelectmentioning

confidence: 99%

“…Recently, state-of-the-art flexible manipulators [23][24][25][26][27][28] have integrated various sensing modalities such as shape and stretch sensing units, tactile sensing units and multi-axis force/torque sensors. For example, the continuum manipulators are integrated with light intensity modulation based fibre optic sensors to measure force/torque [19,23] as well as the manipulators' shape [29] based on stretch sensing elements [49]. The fibre-optic sensors can be designed to provide a high sensing resolution and sensitivity, at a relatively low-cost.…”

Section: A Contact Force Sensor Based On S-shaped Beams and Optoelectmentioning

confidence: 99%

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A Contact Force Sensor Based on S-Shaped Beams and Optoelectronic Sensors for Flexible Manipulators for Minimally Invasive Surgery (MIS)

Noh

Han

Gawenda³

et al. 2020

IEEE Sensors J.

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Flexible, highly articulated robotic tools can greatly facilitate procedures in which the operator needs to access small openings and confined spaces. Particularly, in the context of robotic-assisted minimally invasive surgery (RMIS), the application of such manipulation tools can be significantly beneficial in preventing unnecessary interactions with sensitive body organs by which reducing patient's recovery time when compared with conventional methods. However, these systems usually lack tactile feedback and are not able to perceive and quantify the interactions between themselves and soft body organs. This deficiency may result in damaging the organs due to unwanted excessive force applied. To this end, we introduce a contact force sensor based on three 'dyadic-S-shaped' beams and three optoelectronic sensors. The modular design of a flexible manipulation system described as part of this paper allows ready integration of a series of the proposed sensors within its structure. The sensor uses our novel sensing principle for measuring contact forces. The strategic employment of custom sensor structure and the optoelectronic components fulfill our design objectives which has been focused on the creation of a modular, low-cost, low-noise (electrically) with large voltage variation, without the need for an amplifier, through a simple fabrication process for MIS. Our experimental results, following a very simple calibration processes show the average errors of Fx (+19.37%±0.82,-18.32%±2.06) and Fy (+18.56%±1.69,-17.00%±1.32), and the average RMS errors of Fx (0.12N±0.0067) and Fy (0.11N±0.0032) in the measurement of force values within the range of-4 to 4 N.

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Section: A Contact Force Sensor Based On S-shaped Beams and Optoelectmentioning

confidence: 99%

Section: A Contact Force Sensor Based On S-shaped Beams and Optoelectmentioning

confidence: 99%

A Contact Force Sensor Based on S-Shaped Beams and Optoelectronic Sensors for Flexible Manipulators for Minimally Invasive Surgery (MIS)

Noh

Han

Gawenda³

et al. 2020

IEEE Sensors J.

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“…The measurement range depends on the weight and motion type of the robot. Measurement accuracy is determined by the control requirement of actual motion [ 28 ]. The force sensing system can provide overloaded protection.…”

Section: Design Of Leg Force-sensing Systemmentioning

confidence: 99%

A Force-Sensing System on Legs for Biomimetic Hexapod Robots Interacting with Unstructured Terrain

Zhang

et al. 2017

Sensors

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The tiger beetle can maintain its stability by controlling the interaction force between its legs and an unstructured terrain while it runs. The biomimetic hexapod robot mimics a tiger beetle, and a comprehensive force sensing system combined with certain algorithms can provide force information that can help the robot understand the unstructured terrain that it interacts with. This study introduces a complicated leg force sensing system for a hexapod robot that is the same for all six legs. First, the layout and configuration of sensing system are designed according to the structure and sizes of legs. Second, the joint toque sensors, 3-DOF foot-end force sensor and force information processing module are designed, and the force sensor performance parameters are tested by simulations and experiments. Moreover, a force sensing system is implemented within the robot control architecture. Finally, the experimental evaluation of the leg force sensor system on the hexapod robot is discussed and the performance of the leg force sensor system is verified.

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“…New robotic technologies may produce cheaper systems and new developments such as haptic and tactile sensing and force feedback technology could potentially solve one of the real drawbacks of robotic surgery [5,10,11]. Emergence of competitive companies may indeed contribute to tackling the high cost issue.…”

Section: New Robotic Technologiesmentioning

confidence: 99%

Robotic Surgery, Is It the Future?

Elkak¹

2017

Tumor Res

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Multi-Axis Force/Torque Sensor Based on Simply-Supported Beam and Optoelectronics

Cited by 46 publications

References 42 publications

A Contact Force Sensor Based on S-Shaped Beams and Optoelectronic Sensors for Flexible Manipulators for Minimally Invasive Surgery (MIS)

A Contact Force Sensor Based on S-Shaped Beams and Optoelectronic Sensors for Flexible Manipulators for Minimally Invasive Surgery (MIS)

A Force-Sensing System on Legs for Biomimetic Hexapod Robots Interacting with Unstructured Terrain

Robotic Surgery, Is It the Future?

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