A Voltage Minimization Control Method for Magnetic Navigation Systems to Enhance the Rotating Magnetic Field

IF 4.6 2区计算机科学 Q2 ROBOTICS IEEE Robotics and Automation Letters Pub Date : 2024-11-08 DOI:10.1109/LRA.2024.3495374

Junhyoung Kwon;Junchi Sa;Serim Lee;Gunhee Jang

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Abstract

Magnetic helical robots (MHRs) can be actuated by a rotating magnetic field (RMF) and can tunnel through a clogged blood vessel using their rotational motion. We propose a method minimizing the voltage required for each coil to generate the RMF for a magnetic navigation system (MNS). The proposed method maximizes the RMF under the rated voltage of the MNS. In addition, to suppress the increase in impedance during high-speed rotational motion of the MHR, the proposed method utilizes the resonance to which the minimax optimization method is applied. The voltage needed to generate the RMF was analytically derived, with the goal of a fast optimization process in mind, so that the MHR could be controlled in real-time. The proposed method was experimentally verified by measuring the magnetic flux density. In addition, we demonstrated the enhanced navigating and tunneling performance of the MHR from in vitro experiments. Finally, we validated the navigating and tunneling motion of the MHR in an in vivo experiment within a superficial femoral artery of a pig.

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增强旋转磁场的磁导航系统电压最小化控制方法

磁螺旋机器人（MHR）可由旋转磁场（RMF）驱动，并可利用其旋转运动穿过堵塞的血管。我们提出了一种方法，可最大限度地降低磁导航系统（MNS）每个线圈产生 RMF 所需的电压。在磁导航系统的额定电压下，所提出的方法能使 RMF 最大化。此外，为了抑制 MHR 高速旋转运动时阻抗的增加，所提出的方法利用了共振，在共振中应用了最小优化法。产生 RMF 所需的电压是通过分析得出的，目的是实现快速优化过程，以便实时控制 MHR。通过测量磁通密度，对所提出的方法进行了实验验证。此外，我们还通过体外实验证明了 MHR 增强的导航和隧道性能。最后，我们在猪股浅动脉的体内实验中验证了 MHR 的导航和隧道运动。

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来源期刊

IEEE Robotics and Automation Letters Computer Science-Computer Science Applications

CiteScore

9.60

自引率

15.40%

发文量

1428

期刊介绍： The scope of this journal is to publish peer-reviewed articles that provide a timely and concise account of innovative research ideas and application results, reporting significant theoretical findings and application case studies in areas of robotics and automation.