基于卢恩伯格观测器的微创手术机器人阻力扭矩补偿算法

Hongqiang Sang, Fang Huang, Wei Lu, Rui Han, Fen Liu
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引用次数: 0

摘要

目的 病人侧机械手(PSM)通过将谐波伺服系统与高减速比和低扭矩电机相结合,实现了高扭矩能力。然而,高减速比会增加惯性并降低机械手的顺应性。为了提高微创手术机器人的反向驱动能力,本文旨在提出一种阻力矩补偿算法。设计/方法/途径本文提出了一种基于动力学和卢恩伯格观测器的阻力矩补偿算法。考虑到关节灵活性和改进的 Stribeck 摩擦模型,建立了动力学模型。使用最小二乘法通过实验确定了动态参数。研究结果对于低速手术机器人,可以简化动态模型中的离心力项,以降低计算复杂度。可以考虑关节柔性和改进的 Stribeck 摩擦模型来提高动态模型的精度。实验结果表明,Luenberger 观察器的参数识别和估计结果是准确的。该算法为手术机器人在保持顺应性的同时保持高扭矩提供了潜在的应用前景。同时,机械手反向驱动能力的增强有助于提高术前手动调整的安全性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A resistance torque compensation algorithm based on Luenberger observer for minimally invasive surgical robot

Purpose

The patient-side manipulator (PSM) achieves high torque capability by combining harmonic servo system with high reduction ratio and low torque motor. However, high reduction ratio can increase inertia and decrease compliance of the manipulator. To enhance the backdrivability of the minimally invasive surgical robot, this paper aims to propose a resistance torque compensation algorithm.

Design/methodology/approach

A resistance torque compensation algorithm based on dynamics and Luenberger observer is proposed. The dynamics are established, considering joint flexibility and an improved Stribeck friction model. The dynamic parameters are experimentally identified by using the least squares method. With the advantages of clear structure, simple implementation and fast solution speed, the Luenberger observer is selected to estimate the unmeasured dynamic information of PSM and realize the resistance torque compensation.

Findings

For low-speed surgical robots, the centrifugal force term in the dynamic model can be simplified to reduce computational complexity. Joint flexibility and an improved Stribeck friction model can be considered to improve the accuracy of the dynamic model. Experiment results show that parameter identification and estimated results of the Luenberger observer are accurate. The backdrivability of the PSM is enhanced in ease and smoothness.

Originality/value

This algorithm provides potential application prospects for surgical robots to maintain high torque while remaining compliant. Meanwhile, the enhanced backdrivability of the manipulator helps to improve the safety of the preoperative manual adjustment.

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