A New Impedance Controller Based on Nonlinear Model Reference Adaptive Control for Exoskeleton Systems

被引:7
作者
Gui, Kai [1 ]
Tan, U-Xuan [2 ]
Liu, Honghai [1 ]
Zhang, Dingguo [1 ,3 ]
机构
[1] Shanghai Jiao Tong Univ, State Key Lab Mech Syst & Vibrat, Shanghai 200240, Peoples R China
[2] Singapore Univ Technol & Design, Singapore, Singapore
[3] Univ Bath, Dept Elect & Elect Engn, Bath, Avon, England
来源
INTERNATIONAL JOURNAL OF HUMANOID ROBOTICS | 2019年 / 16卷 / 05期
基金
中国国家自然科学基金;
关键词
Human-robot interaction; compliance control; nonlinear model reference adaptive control; system identification; robotic exoskeleton; DESIGN; ROBOT; TRENDS;
D O I
10.1142/S0219843619500208
中图分类号
TP24 [机器人技术];
学科分类号
080202 ; 1405 ;
摘要
Robotic exoskeletons are expected to show high compliance and low impedance for human-robot interactions (HRIs). Our study introduces a novel method based on nonlinear model reference adaptive control (MRAC) to reduce the inherent impedance and replace the traditional impedance controller in HRIs. The control law and adaptive law are designed according to a candidate Lyapunov function. A simple system identification and initialization method for the nonlinear MRAC is put forward, which provides a set of better initial values for the controller. From the results of simulation and experiment, our controller can reduce the mechanical impedance and achieve high compliance for HRI. The adaptive control and compliance control can be both achieved by the proposed nonlinear MRAC framework.
引用
收藏
页数:20
相关论文
共 50 条
[21]   Decision-Making Model for Adaptive Impedance Control of Teleoperation Systems [J].
Corredor, Javier ;
Sofrony, Jorge ;
Peer, Angelika .
IEEE TRANSACTIONS ON HAPTICS, 2017, 10 (01) :5-16
[22]   Fuzzy cerebellar model articulation controller-based adaptive tracking control for load-carrying exoskeleton [J].
Wu, Han ;
Lang, Lin ;
An, Honglei ;
Wei, Qing ;
Ma, Hongxu .
MEASUREMENT & CONTROL, 2020, 53 (7-8) :1472-1481
[23]   A Novel Controller Dynamic Linearization-Based Model Free Adaptive Predictive Control for A Class Of Discrete Nonlinear Systems [J].
Wang, Danna .
PROCEEDINGS OF THE 2018 INTERNATIONAL CONFERENCE ON MECHANICAL, ELECTRONIC, CONTROL AND AUTOMATION ENGINEERING (MECAE 2018), 2018, 149 :413-421
[24]   Nonlinear time delay estimation based model reference adaptive impedance control for an upper-limb human-robot interaction [J].
Omrani, Javad ;
Moghaddam, Majid M. .
PROCEEDINGS OF THE INSTITUTION OF MECHANICAL ENGINEERS PART H-JOURNAL OF ENGINEERING IN MEDICINE, 2022, 236 (03) :385-398
[25]   Adaptive neural & fuzzy controller for exoskeleton gait pattern control based on musculoskeletal modeling [J].
Gupta, Anjali ;
Semwal, Vijay Bhaskar .
MULTIMEDIA TOOLS AND APPLICATIONS, 2023, 83 (16) :49419-49439
[26]   PI2-Based Adaptive Impedance Control for GaitAdaption of Lower Limb Exoskeleton [J].
Wang, Xingjian ;
Zhang, Runzhi ;
Miao, Yinan ;
An, Mailing ;
Wang, Shaoping ;
Zhang, Yuwei .
IEEE-ASME TRANSACTIONS ON MECHATRONICS, 2024, 29 (06) :4251-4261
[27]   The model reference adaptive impedance control for underwater manipulator compliant operation [J].
Zhang, Jianjun ;
Li, Han ;
Liu, Qunpo ;
Li, Shasha .
TRANSACTIONS OF THE INSTITUTE OF MEASUREMENT AND CONTROL, 2023, 45 (11) :2135-2148
[28]   Trajectory Design and Adaptive Impedance Control of Lower Limb Exoskeleton [J].
An, Mailing ;
Wang, Xingjian ;
Miao, Yinan ;
Wang, Shaoping ;
Miao, Yiqi .
PROCEEDINGS OF THE 2021 IEEE 16TH CONFERENCE ON INDUSTRIAL ELECTRONICS AND APPLICATIONS (ICIEA 2021), 2021, :2037-2042
[29]   Model-reference impedance and admittance control of linear systems [J].
Cunha, Jose Paulo V. S. ;
Costa, Ramon R. .
INTERNATIONAL JOURNAL OF ADAPTIVE CONTROL AND SIGNAL PROCESSING, 2016, 30 (8-10) :1317-1332
[30]   Signal Synthesis Model Reference Adaptive Controller with Genetic Algorithm for a Control of Chemical Tank Reactor [J].
Goud, Harsh ;
Swarnkar, Pankaj .
INTERNATIONAL JOURNAL OF CHEMICAL REACTOR ENGINEERING, 2019, 17 (07)
12345