A Passive Decoupling Mechanism for Misalignment Compensation in Master-Slave Teleoperation
Teleoperated robots are commonly used in minimally invasive surgery as they can control surgical instruments at a distance. An operator sends the motion command via a master console, which must convert these into suitable slave instrument actuator inputs for intuitive interaction. However, most mast...
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th-mahidol.766772022-08-04T15:56:55Z A Passive Decoupling Mechanism for Misalignment Compensation in Master-Slave Teleoperation Shen Treratanakulchai Ferdinando Rodriguez Y. Baena Imperial College London Mahidol University Computer Science Engineering Mathematics Teleoperated robots are commonly used in minimally invasive surgery as they can control surgical instruments at a distance. An operator sends the motion command via a master console, which must convert these into suitable slave instrument actuator inputs for intuitive interaction. However, most master-slave systems available to date use incremental task-space control and clutching, which introduces a discontinuity and orientation misalignment between the master control handle and slave instrument, with a consequent impact on task performance. In this article, we proposed a new master manipulator design to compensate for misalignment mechanically. The modular gimbal consists of a passive decoupling mechanism and a wrist locking feature. After describing the mechanisms and its kinematic configuration, we report on a comparative study under controlled conditions, developed to measure the end effector orientation in both compensated and non-compensated scenarios. The results demonstrate that the compensated master console maintains a near constant end effector orientation over the workspace during clutching, showing great promise as a solution to this outstanding open challenge in master-slave manipulation. 2022-08-04T08:27:27Z 2022-08-04T08:27:27Z 2021-02-01 Article IEEE Transactions on Medical Robotics and Bionics. Vol.3, No.1 (2021), 285-288 10.1109/TMRB.2021.3054829 25763202 2-s2.0-85110964817 https://repository.li.mahidol.ac.th/handle/123456789/76677 Mahidol University SCOPUS https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=85110964817&origin=inward |
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Computer Science Engineering Mathematics Shen Treratanakulchai Ferdinando Rodriguez Y. Baena A Passive Decoupling Mechanism for Misalignment Compensation in Master-Slave Teleoperation |
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Teleoperated robots are commonly used in minimally invasive surgery as they can control surgical instruments at a distance. An operator sends the motion command via a master console, which must convert these into suitable slave instrument actuator inputs for intuitive interaction. However, most master-slave systems available to date use incremental task-space control and clutching, which introduces a discontinuity and orientation misalignment between the master control handle and slave instrument, with a consequent impact on task performance. In this article, we proposed a new master manipulator design to compensate for misalignment mechanically. The modular gimbal consists of a passive decoupling mechanism and a wrist locking feature. After describing the mechanisms and its kinematic configuration, we report on a comparative study under controlled conditions, developed to measure the end effector orientation in both compensated and non-compensated scenarios. The results demonstrate that the compensated master console maintains a near constant end effector orientation over the workspace during clutching, showing great promise as a solution to this outstanding open challenge in master-slave manipulation. |
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Imperial College London |
| author_facet |
Imperial College London Shen Treratanakulchai Ferdinando Rodriguez Y. Baena |
| format |
Article |
| author |
Shen Treratanakulchai Ferdinando Rodriguez Y. Baena |
| author_sort |
Shen Treratanakulchai |
| title |
A Passive Decoupling Mechanism for Misalignment Compensation in Master-Slave Teleoperation |
| title_short |
A Passive Decoupling Mechanism for Misalignment Compensation in Master-Slave Teleoperation |
| title_full |
A Passive Decoupling Mechanism for Misalignment Compensation in Master-Slave Teleoperation |
| title_fullStr |
A Passive Decoupling Mechanism for Misalignment Compensation in Master-Slave Teleoperation |
| title_full_unstemmed |
A Passive Decoupling Mechanism for Misalignment Compensation in Master-Slave Teleoperation |
| title_sort |
passive decoupling mechanism for misalignment compensation in master-slave teleoperation |
| publishDate |
2022 |
| url |
https://repository.li.mahidol.ac.th/handle/123456789/76677 |
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