医疗机器人应用中两个永磁体的混合轨迹规划

Michael Brockdorff, Tomas da Veiga, Joshua Davy, Peter Lloyd, James H Chandler, Giovanni Pittiglio, Ryan K Mathew, Pietro Valdastri
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摘要

以双外部永久磁铁(dEPM)系统的形式对两个大型永久磁铁进行独立的机器人操控,证明了在临床相关尺度上进行多达八个磁自由度(DOF)的驱动,从而增强磁控制的可能性。这种精确的机外控制有助于将磁性制剂用作医疗设备,包括类似导管的软连续机器人(SCR)。使用多个机器人驱动的永久磁铁会带来机器人手臂、环境和病人之间发生碰撞的风险。此外,致动输入之间无约束的转换会导致磁场出现不希望出现的尖峰,从而可能导致不安全的机械手变形。本文提出了一种混合方法,用于 dEPM 平台的轨迹规划。该方法将规划问题一分为二:首先为两个机器人驱动的永磁体找到一条无碰撞的物理路径,然后将其与磁空间路径相结合,从而实现磁场和梯度的平滑变化。这种算法的特点是依次驱动八个磁场 DOF,消除任何可能的碰撞,并将磁场的最大不期望驱动值降低 203.7 mT,将梯度降低 418.7 mT/m。随后,我们通过两个案例研究,考察了这种计划磁场致动对可控硅的影响。首先,将尖端驱动的可控硅移动到限定区域内的设定点。使用建议的规划器驱动后,限制区域外的移动平均减少了 41.3%。最后,在将多段磁性 SCR 引向硅胶脑模型中的动脉瘤部位时,使用建议的磁性规划器显示出其重要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Hybrid trajectory planning of two permanent magnets for medical robotic applications
Independent robotic manipulation of two large permanent magnets, in the form of the dual External Permanent Magnet (dEPM) system has demonstrated the possibility for enhanced magnetic control by allowing for actuation up to eight magnetic degrees of freedom (DOFs) at clinically relevant scales. This precise off-board control has facilitated the use of magnetic agents as medical devices, including catheter-like soft continuum robots (SCRs). The use of multiple robotically actuated permanent magnets poses the risk of collision between the robotic arms, the environment, and the patient. Furthermore, unconstrained transitions between actuation inputs can lead to undesired spikes in magnetic fields potentially resulting in unsafe manipulator deformation. This paper presents a hybrid approach to trajectory planning for the dEPM platform. This is performed by splitting the planning problem in two: first finding a collision-free physical path for the two robotically actuated permanent magnets before combining this with a path in magnetic space, which permits for a smooth change in magnetic fields and gradients. This algorithm was characterized by actuating each of the eight magnetic DOFs sequentially, eliminating any potential collisions and reducing the maximum undesired actuation value by 203.7 mT for fields and by 418.7 mT/m for gradients. The effect of this planned magnetic field actuation on a SCR was then examined through two case studies. First, a tip-driven SCR was moved to set points within a confined area. Actuation using the proposed planner reduced movement outside the restricted area by an average of 41.3%. Lastly, the use of the proposed magnetic planner was shown to be essential in navigating a multi-segment magnetic SCR to the site of an aneurysm within a silicone brain phantom.
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