Developing a Linear Quadratic Regulator for Human Lower Extremity Exoskeleton Robot

IF 0.9 Q4 ROBOTICS

Journal of Robotics and Mechatronics Pub Date : 2022-01-01 DOI:10.3844/jmrsp.2022.28.46

S. Hasan, A. Dhingra

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引用次数: 2

Abstract

Corresponding Author: Sk Khairul Hasan Department of Mechanical and Manufacturing Engineering, Miami University, USA E-mail: hasansk@miamioh.edu Abstract: During the last two decades, exoskeleton robot-assisted neurorehabilitation has received a lot of attention. The major reason for active research in robot-assisted rehabilitation is its ability to provide various types of physical therapy at different stages of physical and neurological recovery. The performance of the robot-assisted physical therapy is greatly influenced by the robot motion control system. Robot dynamics are nonlinear, but many linear control schemes can adequately handle the nonlinear dynamics with the help of feedback linearization techniques. In this study, the dynamic model of the human lower extremities was developed. A state-space form of the human lower extremity nonlinear dynamic model is presented. LuGre friction model was used to simulate the robot joint friction. A Linear Quadratic Regulator (LQR) was designed to control the human lower extremity dynamics. Dynamic simulations were carried out in the MatlabSimulink environment. The designed controller's tracking performance was demonstrated in the presence of joint friction. The developed controller’s tracking performance is assessed by comparing the results obtained using LQR with other linear and nonlinear controllers (PID, Computed torque control, and Sliding mode control). For performance verification, the same robot dynamics, friction model, and trajectories were used. The stability of the developed control system is also analyzed.

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人类下肢外骨骼机器人线性二次型调节器的研制

摘要:近二十年来，外骨骼机器人辅助神经康复研究受到了广泛的关注。机器人辅助康复研究活跃的主要原因是它能够在身体和神经恢复的不同阶段提供各种类型的物理治疗。机器人运动控制系统对机器人辅助物理治疗的效果有很大影响。机器人动力学是非线性的，但许多线性控制方案借助反馈线性化技术可以充分处理非线性动力学。在本研究中，建立了人体下肢的动力学模型。提出了一种人体下肢非线性动力学模型的状态空间形式。采用LuGre摩擦模型对机器人关节摩擦进行仿真。设计了一种线性二次型调节器(LQR)来控制人体下肢动力学。在MatlabSimulink环境下进行了动态仿真。在存在关节摩擦的情况下，验证了所设计控制器的跟踪性能。通过比较LQR与其他线性和非线性控制器(PID、计算转矩控制和滑模控制)获得的结果来评估所开发的控制器的跟踪性能。为了进行性能验证，使用了相同的机器人动力学、摩擦模型和轨迹。对所开发的控制系统的稳定性进行了分析。

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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来源期刊

Journal of Robotics and Mechatronics ROBOTICS-

CiteScore

2.20

自引率

36.40%

发文量

134

期刊介绍： First published in 1989, the Journal of Robotics and Mechatronics (JRM) has the longest publication history in the world in this field, publishing a total of over 2,000 works exclusively on robotics and mechatronics from the first number. The Journal publishes academic papers, development reports, reviews, letters, notes, and discussions. The JRM is a peer-reviewed journal in fields such as robotics, mechatronics, automation, and system integration. Its editorial board includes wellestablished researchers and engineers in the field from the world over. The scope of the journal includes any and all topics on robotics and mechatronics. As a key technology in robotics and mechatronics, it includes actuator design, motion control, sensor design, sensor fusion, sensor networks, robot vision, audition, mechanism design, robot kinematics and dynamics, mobile robot, path planning, navigation, SLAM, robot hand, manipulator, nano/micro robot, humanoid, service and home robots, universal design, middleware, human-robot interaction, human interface, networked robotics, telerobotics, ubiquitous robot, learning, and intelligence. The scope also includes applications of robotics and automation, and system integrations in the fields of manufacturing, construction, underwater, space, agriculture, sustainability, energy conservation, ecology, rescue, hazardous environments, safety and security, dependability, medical, and welfare.