利用绳网结构模拟手术机器人切割薄型可变形材料的过程

IF 3.4 Q2 ENGINEERING, BIOMEDICAL IEEE transactions on medical robotics and bionics Pub Date : 2024-10-07 DOI:10.1109/TMRB.2024.3475509
Mustafa Haiderbhai;Lueder A. Kahrs
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引用次数: 0

摘要

手术机器人自主切割的传统方法依赖于基于轨迹的规划算法。这些方法无法补偿软材料的动态变化,如变形和拓扑变化。要应用强化学习(RL)等最新进展,需要对软材料切割进行模拟建模。在这项工作中,我们利用达芬奇研究工具包(dVRK)开发了一种用于切割可变形网格的手术机器人仿真环境。我们的环境使用基于粒子的物理仿真来模拟绳网结构,以创建逼真的物理行为和视觉渲染。切割是使用 EndoWrist 圆头剪刀(RTS),通过碰撞检查和回调系统来检测和更新切割。为了展示可变形网格剪切模拟,我们设计了一项剪切任务,即沿着所需的路径剪切,可通过手动控制来解决。网格结构可用于渲染不同的材料,我们重点介绍了如何使网格结构类似于可变形的组织或织物,同时保持稳定,没有明显的伪影。该环境是训练自主代理切割二维可变形材料的垫脚石,并可用于切割更复杂的可变形形状。
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Simulating Surgical Robot Cutting of Thin Deformable Materials Using a Rope Grid Structure
Traditional methods for autonomous cutting in surgical robotics have relied on trajectory-based planning algorithms. These methods fail to compensate for dynamic changes in soft materials such as deformation and topological change. To apply recent advances such as reinforcement learning (RL), a simulation is needed that models the cutting of soft materials. In this work, we develop a surgical robotics simulation environment for cutting deformable meshes with the da Vinci Research Kit (dVRK). Our environment is built using a particle-based physics simulation to simulate a rope grid structure to create realistic physics behavior and visual rendering. Cutting is implemented with the EndoWrist Round Tip Scissors (RTS) through a system of collision checking and callbacks to detect and update cuts. To showcase the deformable mesh cutting simulation, we design a cutting task of cutting along a desired path that can be solved through manual control. The grid structure can be adapted to render different materials, and we highlight how it can be made to resemble deformable tissue or fabric while being stable with no visible artifacts. This environment is a stepping stone towards training autonomous agents for cutting 2D deformable materials and building towards cutting more complex deformable shapes.
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Table of Contents IEEE Transactions on Medical Robotics and Bionics Society Information Guest Editorial Special section on the Hamlyn Symposium 2023—Immersive Tech: The Future of Medicine IEEE Transactions on Medical Robotics and Bionics Publication Information IEEE Transactions on Medical Robotics and Bionics Information for Authors
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