Autonomous path planning and stabilizing force interaction control for robotic massage in unknown environment

Xiaoqing Zhang, Genliang Xiong, Peng Yin, Yanfeng Gao, Yan Feng
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Abstract

Purpose

To ensure the motion attitude and stable contact force of massage robot working on unknown human tissue environment, this study aims to propose a robotic system for autonomous massage path planning and stable interaction control.

Design/methodology/approach

First, back region extraction and acupoint recognition based on deep learning is proposed, which provides a basis for determining the working area and path points of the robot. Second, to realize the standard approach and movement trajectory of the expert massage, 3D reconstruction and path planning of the massage area are performed, and normal vectors are calculated to control the normal orientation of robot-end. Finally, to cope with the soft and hard changes of human tissue state and body movement, an adaptive force tracking control strategy is presented to compensate the uncertainty of environmental position and tissue hardness online.

Findings

Improved network model can accomplish the acupoint recognition task with a large accuracy and integrate the point cloud to generate massage trajectories adapted to the shape of the human body. Experimental results show that the adaptive force tracking control can obtain a relatively smooth force, and the error is basically within ± 0.2 N during the online experiment.

Originality/value

This paper incorporates deep learning, 3D reconstruction and impedance control, the robot can understand the shape features of the massage area and adapt its planning massage path to carry out a stable and safe force tracking control during dynamic robot–human contact.

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未知环境中机器人按摩的自主路径规划和稳定力交互控制
目的为了保证按摩机器人在未知人体组织环境中工作时的运动姿态和稳定的接触力,本研究旨在提出一种自主按摩路径规划和稳定交互控制的机器人系统。设计/方法/途径首先,提出基于深度学习的背部区域提取和穴位识别,为确定机器人的工作区域和路径点提供依据。其次,为实现专家按摩的标准方法和运动轨迹,对按摩区域进行三维重建和路径规划,并计算法向量以控制机器人末端的法线方向。最后,为了应对人体组织状态和身体运动的软硬变化,提出了一种自适应力跟踪控制策略,以在线补偿环境位置和组织硬度的不确定性。实验结果表明,自适应力跟踪控制可以获得相对平稳的力,在线实验中误差基本在±0.2 N以内。 原创性/价值本文结合深度学习、三维重建和阻抗控制,机器人可以理解按摩区域的形状特征,并调整其规划按摩路径,在机器人与人体动态接触过程中进行稳定、安全的力跟踪控制。
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