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Development of a wireless hybrid microrobot for biomedical applications

In this paper, to deal with the locomotion and performance in pipe or even in blood vessel condition, we design a novel type of hybrid microrobot that has characteristics of multi-functions, controllability, stability. The hybrid microrobot has simple structure, simple control method, and good dynam...

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Main Authors:	Qinxue Pan, Shuxiang Guo, Okada, Takuya
Format:	Conference Proceeding
Language:	English
Subjects:	Coils Current measurement Magnetic fields Magnetic flux Robots Solenoids Wireless communication
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creator	Qinxue Pan Shuxiang Guo Okada, Takuya
description	In this paper, to deal with the locomotion and performance in pipe or even in blood vessel condition, we design a novel type of hybrid microrobot that has characteristics of multi-functions, controllability, stability. The hybrid microrobot has simple structure, simple control method, and good dynamic. We develop the microrobot composed of rotating motion and fish-like locomotion to realize the wireless controllability capable of swimming and rotating motion. We design the rotation magnetic field, the motion mechanism of rotating motion and fish-like motions have been analyzed as well. Also, we design the hybrid microrobot by combining the rotating motion and fish-like fin motion. By applying the rotation magnetic field, we carried out the evaluating experiments for rotating motion and moving motion in a pipe. The experimental results indicated that, for the rotating motion, the rotating speed of 87rad/s and moving speed of 58mm/s; for the hybrid microrobot, the moving speed of 48mm/s can be obtained via frequency of the input current. Additionally, it is demonstrated that the microrobot has a rapid response. This microrobot will play an important role in both industrial and medical applications such as microsurgery.
doi_str_mv	10.1109/IROS.2010.5652965
format	conference_proceeding
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The hybrid microrobot has simple structure, simple control method, and good dynamic. We develop the microrobot composed of rotating motion and fish-like locomotion to realize the wireless controllability capable of swimming and rotating motion. We design the rotation magnetic field, the motion mechanism of rotating motion and fish-like motions have been analyzed as well. Also, we design the hybrid microrobot by combining the rotating motion and fish-like fin motion. By applying the rotation magnetic field, we carried out the evaluating experiments for rotating motion and moving motion in a pipe. The experimental results indicated that, for the rotating motion, the rotating speed of 87rad/s and moving speed of 58mm/s; for the hybrid microrobot, the moving speed of 48mm/s can be obtained via frequency of the input current. Additionally, it is demonstrated that the microrobot has a rapid response. 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source	IEEE Electronic Library (IEL) Conference Proceedings
subjects	Coils Current measurement Magnetic fields Magnetic flux Robots Solenoids Wireless communication
title	Development of a wireless hybrid microrobot for biomedical applications
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