|Table of Contents|

Force and position control for lower limb rehabilitationexoskeleton based on impedance(PDF)

《南京理工大学学报》(自然科学版)[ISSN:1005-9830/CN:32-1397/N]

Issue:
2020年01期
Page:
21-25
Research Field:
Publishing date:

Info

Title:
Force and position control for lower limb rehabilitationexoskeleton based on impedance
Author(s):
Peng Erbao12Chen Changduo2
1.School of Mechanical and Electrical Engineering,Wuhan University of Technology,Wuhan 430000,China; 2. Henan Polytechnic Institute,Nanyang 473000,China
Keywords:
lower limb rehabilitation exoskeleton force and position control impedance control pneumatic drive humanoid gait
PACS:
TP242; TP273
DOI:
10.14177/j.cnki.32-1397n.2020.44.01.004
Abstract:
In order to improve the comfort and rehabilitation effect of patients with lower limb functional injury,and make up for the conventional position control,a lower limb rehabilitation exoskeleton based on force and position impedance control is designed. Using the flexibility and safety of gas and based on pneumatic proportional technology,it can be controlled real-time,which takes standard gait curve as reference and human-computer interaction moment as constraint. The human-machine dynamic model is established,the experimental platform was built,and the humanoid walking was realized. The experimental results show that the control effect is good,the tracking precision is high,the man-machine interaction torque is effectively adjusted,and the system safety,comfort and stability are further improved.

References:

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Last Update: 2020-02-29