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一种用于泰勒型模型预测控制的新投影活动集共轭梯度法:应用于具有被动和主动康复功能的下肢康复机器人

A New Projected Active Set Conjugate Gradient Approach for Taylor-Type Model Predictive Control: Application to Lower Limb Rehabilitation Robots With Passive and Active Rehabilitation.

作者信息

Shi Tian, Tian Yantao, Sun Zhongbo, Zhang Bangcheng, Pang Zaixiang, Yu Junzhi, Zhang Xin

机构信息

College of Communication Engineering, Jilin University, Changchun, China.

Department of Control Engineering, Changchun University of Technology, Changchun, China.

出版信息

Front Neurorobot. 2020 Dec 3;14:559048. doi: 10.3389/fnbot.2020.559048. eCollection 2020.

DOI:10.3389/fnbot.2020.559048
PMID:33343324
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7744727/
Abstract

In this paper, a three-order Taylor-type numerical differentiation formula is firstly utilized to linearize and discretize constrained conditions of model predictive control (MPC), which can be generalized from lower limb rehabilitation robots. Meanwhile, a new numerical approach that projected an active set conjugate gradient approach is proposed, analyzed, and investigated to solve MPC. This numerical approach not only incorporates both the active set and conjugate gradient approach but also utilizes a projective operator, which can guarantee that the equality constraints are always satisfied. Furthermore, rigorous proof of feasibility and global convergence also shows that the proposed approach can effectively solve MPC with equality and bound constraints. Finally, an echo state network (ESN) is established in simulations to realize intention recognition for human-machine interactive control and active rehabilitation training of lower-limb rehabilitation robots; simulation results are also reported and analyzed to substantiate that ESN can accurately identify motion intention, and the projected active set conjugate gradient approach is feasible and effective for lower-limb rehabilitation robot of MPC with passive and active rehabilitation training. This approach also ensures computational when disturbed by uncertainties in system.

摘要

本文首先利用三阶泰勒型数值微分公式对模型预测控制(MPC)的约束条件进行线性化和离散化,该公式可从下肢康复机器人推广而来。同时,提出、分析并研究了一种新的数值方法——投影活动集共轭梯度法来求解MPC。这种数值方法不仅结合了活动集和共轭梯度法,还利用了投影算子,可确保等式约束始终得到满足。此外,对可行性和全局收敛性的严格证明还表明,所提方法能够有效求解具有等式和边界约束的MPC。最后,在仿真中建立了回声状态网络(ESN),以实现下肢康复机器人人机交互控制和主动康复训练的意图识别;还报告并分析了仿真结果,以证实ESN能够准确识别运动意图,且投影活动集共轭梯度法对于具有被动和主动康复训练的下肢康复机器人MPC是可行且有效的。该方法还确保了在系统受到不确定性干扰时的计算能力。

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本文引用的文献

1
RNN for Perturbed Manipulability Optimization of Manipulators Based on a Distributed Scheme: A Game-Theoretic Perspective.
IEEE Trans Neural Netw Learn Syst. 2020 Dec;31(12):5116-5126. doi: 10.1109/TNNLS.2020.2963998. Epub 2020 Nov 30.
2
Complex-Valued Discrete-Time Neural Dynamics for Perturbed Time-Dependent Complex Quadratic Programming With Applications.用于受扰时变复二次规划的复值离散时间神经动力学及其应用。
IEEE Trans Neural Netw Learn Syst. 2020 Sep;31(9):3555-3569. doi: 10.1109/TNNLS.2019.2944992. Epub 2019 Nov 8.
3
Robust model predictive control of nonlinear systems with unmodeled dynamics and bounded uncertainties based on neural networks.基于神经网络的具有未建模动态和有界不确定性的非线性系统的鲁棒模型预测控制。
IEEE Trans Neural Netw Learn Syst. 2014 Mar;25(3):457-69. doi: 10.1109/TNNLS.2013.2275948.
4
Poststroke spasticity: sequelae and burden on stroke survivors and caregivers.脑卒中后痉挛:后遗症及对脑卒中幸存者和照护者的负担。
Neurology. 2013 Jan 15;80(3 Suppl 2):S45-52. doi: 10.1212/WNL.0b013e3182764c86.
5
Modeling nonlinear errors in surface electromyography due to baseline noise: a new methodology.基于基线噪声的表面肌电非线性误差建模:一种新方法。
J Biomech. 2011 Jan 4;44(1):202-5. doi: 10.1016/j.jbiomech.2010.09.008. Epub 2010 Sep 25.
6
Neuromusculoskeletal modeling: estimation of muscle forces and joint moments and movements from measurements of neural command.神经肌肉骨骼建模:根据神经指令测量值估计肌肉力量、关节力矩和运动。
J Appl Biomech. 2004 Nov;20(4):367-95. doi: 10.1123/jab.20.4.367.
7
Investigation of the Hammerstein hypothesis in the modeling of electrically stimulated muscle.在电刺激肌肉建模中对哈默斯坦假设的研究。
IEEE Trans Biomed Eng. 1998 Aug;45(8):998-1009. doi: 10.1109/10.704868.