2022
DOI: 10.1109/lra.2022.3187249
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A Simulation Framework for Magnetic Continuum Robots

Abstract: Remote magnetic navigation is a technology used to robotically steer magnetic medical instruments, such as magnetic catheters and guidewires, for minimally invasive surgery. The ability to model and simulate the behavior of these magnetic instruments in complex anatomies is important for their clinical use in many ways. Simulation frameworks can improve their design, characterization, and automatic control capabilities, as well as provide training simulators for physicians. In this work we introduce a new simu… Show more

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Cited by 19 publications
(20 citation statements)
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“…[135] The configuration of equipping multiple permanent magnets distributed along the tip has also been explored. [106,111,141,142] For instance, Armacost et al proposed . Magnetic guidewires and catheters based on permanent magnets and magnetic particles.…”
Section: Magnetic Guidewire and Cathetermentioning
confidence: 99%
See 1 more Smart Citation
“…[135] The configuration of equipping multiple permanent magnets distributed along the tip has also been explored. [106,111,141,142] For instance, Armacost et al proposed . Magnetic guidewires and catheters based on permanent magnets and magnetic particles.…”
Section: Magnetic Guidewire and Cathetermentioning
confidence: 99%
“…[ 135 ] The configuration of equipping multiple permanent magnets distributed along the tip has also been explored. [ 106,111,141,142 ] For instance, Armacost et al proposed a three‐magnet‐tip catheter, which had the ability to generate a more significant deflection and a more rapid turning compared with the single‐magnetic design (Figure 7b). [ 106 ] They also derived a comprehensive mathematical model to predict the position and deflection of the catheter, taking both the magnetic torques and forces into consideration.…”
Section: Magnetic Continuum Robotmentioning
confidence: 99%
“…This characteristic not only enables rapid iteration and optimization of learning algorithms, it also enables realistic human interaction, which is relevant for recording (expert) demonstrations and validating human-robot collaboration. SOFA is an active open source project that is continuously increasing in popularity, attracting new contributors and accruing new features such as dynamic mesh refinement, control of magnetic continuum robots (Dreyfus et al, 2022), and synthetic data generation from numerical simulations for training machine learning models (Mimesis Inria Research Team, 2022;Linkerhägner et al, 2023).…”
Section: Sofamentioning
confidence: 99%
“…The aim of these tools is to provide both experienced SOFA users and newcomers with an easy-to-use framework for RL. To demonstrate sofa env's ease of use, we port the existing SOFA simulation from Dreyfus et al (2022) and define a RL environment for its task. The scene contains a magnetic continuum robot that is controlled through an external force field in order to navigate in a model of (a) an aortic arch and (b) a 2D toy scene, as shown in Figure 3.…”
Section: Implementation Of New Environmentsmentioning
confidence: 99%
“…Most systems with paired coils tend to enclose the workspace via circular [17] or square [15] coils with air cores. In contrast, distributed electromagnet-based systems usually have columnar [18] or rectangular [19] coils positioned around and pointing towards the workspace. For general electromagnets, iron cores made of soft magnetic materials with low hysteresis and high permeability are often installed inside the coils to increase the magnetic field intensity [4], [20].…”
Section: Introductionmentioning
confidence: 99%