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Equitranslational and axially rotational microrobot using electromagnetic actuation system
Recently, many researchers have focused on wireless microrobots as therapeutic agents for active drug delivery. Owing to their size limitation, they cannot be equipped with actuators/sensors, controllers and batteries. Therefore, external devices (magnetic field generator, position recognition devic...
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| Published in: | International journal of control, automation, and systems 2017, Automation, and Systems, 15(3), , pp.1342-1350 |
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| cited_by | cdi_FETCH-LOGICAL-c350t-6075378a20b610bc8cc6c0f8fb3dde3619b0d1ede28147f96405e453d3d712b73 |
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| cites | cdi_FETCH-LOGICAL-c350t-6075378a20b610bc8cc6c0f8fb3dde3619b0d1ede28147f96405e453d3d712b73 |
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| container_title | International journal of control, automation, and systems |
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| creator | Choi, Hyunchul Jeong, Semi Go, Gwangjun Lee, Cheong Zhen, Jin Ko, Seong Young Park, Jong-Oh Park, Sukho |
| description | Recently, many researchers have focused on wireless microrobots as therapeutic agents for active drug delivery. Owing to their size limitation, they cannot be equipped with actuators/sensors, controllers and batteries. Therefore, external devices (magnetic field generator, position recognition devices, and control system) are used to realize the main functions (locomotion, sensing, and therapy) of biomedical microrobots and thus, to minimize their size. Especially, the small wireless microrobots, inserted into the human body, should have various steering, locomotive, and therapeutic functions for diagnosis and treatment. Generally, an external magnetic field is widely used for the locomotion of a wireless microrobot. However, microrobots using an external magnetic field cannot simultaneously realize equitranslational and axial rotational motions in the same microrobot system. In this paper, we developed an electromagnetic actuation (EMA) system and a spiral-shape microrobot and proposed its actuating algorithm. The developed wireless microrobot can show equitranslation and axial rotation in the same microrobot system. Finally, various experiments in a test-bed and in a blood vessel phantom validated that the developed microrobot can move to a target position by equitranslation and can penetrate a thrombus model by axial rotation. |
| doi_str_mv | 10.1007/s12555-016-0146-z |
| format | article |
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Owing to their size limitation, they cannot be equipped with actuators/sensors, controllers and batteries. Therefore, external devices (magnetic field generator, position recognition devices, and control system) are used to realize the main functions (locomotion, sensing, and therapy) of biomedical microrobots and thus, to minimize their size. Especially, the small wireless microrobots, inserted into the human body, should have various steering, locomotive, and therapeutic functions for diagnosis and treatment. Generally, an external magnetic field is widely used for the locomotion of a wireless microrobot. However, microrobots using an external magnetic field cannot simultaneously realize equitranslational and axial rotational motions in the same microrobot system. In this paper, we developed an electromagnetic actuation (EMA) system and a spiral-shape microrobot and proposed its actuating algorithm. The developed wireless microrobot can show equitranslation and axial rotation in the same microrobot system. 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J. Control Autom. Syst</addtitle><description>Recently, many researchers have focused on wireless microrobots as therapeutic agents for active drug delivery. Owing to their size limitation, they cannot be equipped with actuators/sensors, controllers and batteries. Therefore, external devices (magnetic field generator, position recognition devices, and control system) are used to realize the main functions (locomotion, sensing, and therapy) of biomedical microrobots and thus, to minimize their size. Especially, the small wireless microrobots, inserted into the human body, should have various steering, locomotive, and therapeutic functions for diagnosis and treatment. Generally, an external magnetic field is widely used for the locomotion of a wireless microrobot. However, microrobots using an external magnetic field cannot simultaneously realize equitranslational and axial rotational motions in the same microrobot system. 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However, microrobots using an external magnetic field cannot simultaneously realize equitranslational and axial rotational motions in the same microrobot system. In this paper, we developed an electromagnetic actuation (EMA) system and a spiral-shape microrobot and proposed its actuating algorithm. The developed wireless microrobot can show equitranslation and axial rotation in the same microrobot system. Finally, various experiments in a test-bed and in a blood vessel phantom validated that the developed microrobot can move to a target position by equitranslation and can penetrate a thrombus model by axial rotation.</abstract><cop>Bucheon / Seoul</cop><pub>Institute of Control, Robotics and Systems and The Korean Institute of Electrical Engineers</pub><doi>10.1007/s12555-016-0146-z</doi><tpages>9</tpages></addata></record> |
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| ispartof | International Journal of Control, 2017, Automation, and Systems, 15(3), , pp.1342-1350 |
| issn | 1598-6446 2005-4092 |
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| source | ABI/INFORM Global; Springer Nature |
| subjects | Actuation Algorithms Chemical compounds Control Devices Drug delivery systems Electromagnetics Engineering Experiments Locomotion Magnetic fields Mechatronics Medical equipment Microrobots Pharmacology Position sensing Regular Papers Robotics Robots Studies Wireless communications 제어계측공학 |
| title | Equitranslational and axially rotational microrobot using electromagnetic actuation system |
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