A Computational Framework for Complementary Situational Awareness (CSA) in Surgical Assistant Robots

Preetham Chalasani, A. Deguet, P. Kazanzides, R. Taylor
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引用次数: 11

Abstract

Robotic surgical systems have contributed greatly to the advancement of minimally invasive surgery (MIS). More specifically, telesurgical robots have provided enhanced dexterity to surgeons performing MIS procedures. However, current robotic teleoperated systems have only limited situational awareness of the patient anatomy and surgical environment that would typically be available to a surgeon in an open surgery. Although the endoscopic view enhances the visualization of the anatomy, perceptual understanding of the environment and anatomy is still lacking due to the absence of sensory feedback. To address these limitations, we present an algorithmic software framework to provide Complementary Situational Awareness (CSA) in a surgical assistant. This framework aims at improving the human-robot relationship by providing elaborate guidance and sensory feedback capabilities for the surgeon in complex MIS procedures. Unlike traditional teleoperation, this framework enables the user to telemanipulate the situational model in a virtual environment and uses that information to command the slave robot with appropriate admittance gains and environmental constraints. Simultaneously, the situational model is updated based on interaction of the slave robot with the task space environment. We provide various high-level and mid-level components to provide CSA and illustrate the necessary capabilities required for any robotic platform to readily incorporate CSA. We also demonstrate the use of our framework for constrained model-mediated teleoperation using the open-source da Vinci Research Kit (dVRK) hardware.
手术辅助机器人互补态势感知(CSA)计算框架
机器人手术系统为微创手术(MIS)的发展做出了巨大贡献。更具体地说,远程手术机器人为外科医生执行MIS程序提供了更高的灵活性。然而,目前的机器人远程操作系统只有有限的病人解剖和手术环境的态势感知,这通常是外科医生在开放手术中可用的。虽然内窥镜视图增强了解剖的可视化,但由于缺乏感觉反馈,仍然缺乏对环境和解剖的感性理解。为了解决这些限制,我们提出了一种算法软件框架,以在手术助手中提供补充态势感知(CSA)。该框架旨在通过在复杂的MIS程序中为外科医生提供详细的指导和感觉反馈能力来改善人机关系。与传统的远程操作不同,该框架使用户能够在虚拟环境中远程操作情境模型,并使用该信息在适当的导纳增益和环境约束下指挥从机器人。同时,基于从机器人与任务空间环境的交互,更新了态势模型。我们提供了各种高级和中级组件来提供CSA,并说明了任何机器人平台轻松集成CSA所需的必要功能。我们还演示了使用开源达芬奇研究工具包(dVRK)硬件的约束模型介导远程操作框架的使用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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