Adaptive CPG-Based Impedance Control for Assistive Lower Limb Exoskeleton

机译：基于CPG的基于CPG的阻抗控制，用于辅助下肢外骨骼

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Adaptation to user's impedance properties has been viewed imperative in developing assistive exoskeletons. However, most exoskeletons are still rather controlled with predefined joint trajectories. Inspired by the success in locomotion control for humanoid robots using central pattern generator (CPG) and impedance control for human-robot interaction, an impedance control based on CPG that can adapt to human's impedance properties is presented in this work. The proposed method is validated by a simulation in MATLAB/Simulink, integrating a 6-DOF lower limb exoskeleton model with a musculoskeletal human model. Simulation results indicate that the lower limb exoskeleton, incorporating the proposed adaptive CPG-based impedance controller, can effectively assist human walking.

机译：在开发辅助外骨骼中，对用户的阻抗特性进行了适应。然而，大多数外骨骼仍然相当于预定义的关节轨迹控制。灵感来自使用中央图案发生器（CPG）的人形机器人的运动机器人的成功和用于人机交互的阻抗控制，在这项工作中提出了基于可以适应人类阻抗特性的CPG的阻抗控制。通过Matlab / Simulink的模拟验证所提出的方法，与肌肉骨骼人模型集成6-DOF下肢外骨骼模型。仿真结果表明，下肢外骨骼，包含所提出的基于CPG的阻抗控制器，可以有效地帮助人类走路。

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《IEEE International Conference on Robotics and Biomimetics》|2018年|1 v.|共6页
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Ruiming Luo; Shouqian Sun; Xiangyu Zhao; Yuxuan Zhang; Yongchuan Tang;
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中图分类机器人技术;
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Conferences; Robots; Biomimetics; Machine-to-machine communications;

机译：会议;机器人;生物体;机器到机器通信;

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专利

1. Muscle circumference sensor and model reference-based adaptive impedance control for upper limb assist exoskeleton robot [J] . Khan Abdul Manan, Usman Muhammad, Ali Ahmad, Advanced Robotics: The International Journal of the Robotics Society of Japan . 2016,第23a24期

机译：上肢辅助外骨骼机器人的肌肉圆周传感器和基于模型参考的自适应阻抗控制
2. An Adaptive Neuromuscular Controller for Assistive Lower-Limb Exoskeletons: A Preliminary Study on Subjects with Spinal Cord Injury [J] . Wu, Amy R. Frontiers in Neurorobotics . 2017,第2016期

机译：辅助下肢外骨骼的自适应神经肌肉控制器：脊髓损伤的受试者的初步研究。
3. An Adaptive Neuromuscular Controller for Assistive Lower-Limb Exoskeletons: A Preliminary Study on Subjects with Spinal Cord Injury [J] . Amy R. Wu, Florin Dzeladini, Tycho J. H. Brug, Frontiers in Neurorobotics . 2017,第4期

机译：辅助下肢外骨骼的自适应神经肌肉控制器：脊髓损伤的受试者的初步研究。
4. Adaptive CPG-Based Impedance Control for Assistive Lower Limb Exoskeleton [C] . Ruiming Luo, Shouqian Sun, Xiangyu Zhao, IEEE International Conference on Robotics and Biomimetics . 2018

机译：基于自适应CPG的辅助下肢外骨骼阻抗控制
5. Active impedance control of a lower-limb assistive exoskeleton. [D] . Aguirre-Ollinger, Gabriel. 2009

机译：下肢辅助外骨骼的主动阻抗控制。
6. An Adaptive Neuromuscular Controller for Assistive Lower-Limb Exoskeletons: A Preliminary Study on Subjects with Spinal Cord Injury [O] . Amy R. Wu, Florin Dzeladini, Tycho J. H. Brug, 2017

机译：辅助下肢外骨骼的自适应神经肌肉控制器：脊髓损伤的受试者的初步研究。
7. Active-impedance control of a lower-limb assistive exoskeleton [O] . Gabriel Aguirre-ollinger, J. Edward Colgate, Michael A. Peshkin, 2016

机译：下肢辅助外骨骼的主动阻抗控制

Adaptive CPG-Based Impedance Control for Assistive Lower Limb Exoskeleton

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