Intrinsic Sensing and Evolving Internal Model Control of Compact Elastic Module for a Lower Extremity Exoskeleton

To achieve strength augmentation, endurance enhancement, and human assistance in a functional autonomous exoskeleton, control precision, back drivability, low output impedance, and mechanical compactness are desired. In our previous work, two elastic modules were designed for human–robot interaction sensing and compliant control, respectively. According to the intrinsic sensing properties of the elastic module, in this paper, only one compact elastic module is applied to realize both purposes. Thus, the corresponding control strategy is required and evolving internal model control is proposed to address this issue. Moreover, the input signal to the controller is derived from the deflection of the compact elastic module. The human–robot interaction is considered as the disturbance which is approximated by the output error between the exoskeleton control plant and evolving forward learning model. Finally, to verify our proposed control scheme, several experiments are conducted with our robotic exoskeleton system. The experiment shows a satisfying result and promising application feasibility.

[1]  Yasuhisa Hasegawa,et al.  Gait support for complete spinal cord injury patient by synchronized leg-swing with HAL , 2011, 2011 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[2]  Wen-Hua Chen,et al.  Disturbance observer based control for nonlinear systems , 2004, IEEE/ASME Transactions on Mechatronics.

[3]  Gregor Gregorcic,et al.  Internal model control based on a Gaussian process prior model , 2003, Proceedings of the 2003 American Control Conference, 2003..

[4]  Kevin Cleary,et al.  Closed-Loop Force Control for Haptic Simulation of Virtual Environments , 2000 .

[5]  Carlos E. Garcia,et al.  Internal model control. A unifying review and some new results , 1982 .

[6]  Masayoshi Tomizuka,et al.  A gait rehabilitation strategy inspired by an iterative learning algorithm , 2012 .

[7]  Zoubin Ghahramani,et al.  Sparse Gaussian Processes using Pseudo-inputs , 2005, NIPS.

[8]  Riccardo Muradore,et al.  Impedance control of series elastic actuators: Passivity and acceleration-based control , 2017 .

[9]  G. Kitagawa Monte Carlo Filter and Smoother for Non-Gaussian Nonlinear State Space Models , 1996 .

[10]  Paolo Fiorini,et al.  Human-adaptive control of series elastic actuators , 2014, Robotica.

[11]  Paolo Fiorini,et al.  A Rationale for Acceleration Feedback in Force Control of Series Elastic Actuators , 2018, IEEE Transactions on Robotics.

[12]  Marc Peter Deisenroth,et al.  Distributed Gaussian Processes , 2015, ICML.

[13]  Peter J. Gawthrop,et al.  A nonlinear disturbance observer for robotic manipulators , 2000, IEEE Trans. Ind. Electron..

[14]  Suin Kim,et al.  Force-Mode Control of Rotary Series Elastic Actuators in a Lower Extremity Exoskeleton Using Model-Inverse Time Delay Control , 2017, IEEE/ASME Transactions on Mechatronics.

[15]  Martin Tegenthoff,et al.  Impact of locomotion training with a neurologic controlled hybrid assistive limb (HAL) exoskeleton on neuropathic pain and health related quality of life (HRQoL) in chronic SCI: a case study* , 2014, Disability and rehabilitation. Assistive technology.

[16]  Rahsaan J. Holley,et al.  Development and pilot testing of HEXORR: Hand EXOskeleton Rehabilitation Robot , 2010, Journal of NeuroEngineering and Rehabilitation.

[17]  H. van der Kooij,et al.  Design of a series elastic- and Bowden cable-based actuation system for use as torque-actuator in exoskeleton-type training , 2005, 9th International Conference on Rehabilitation Robotics, 2005. ICORR 2005..

[18]  Martin Buss,et al.  Passive and accurate torque control of series elastic actuators , 2007, 2007 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[19]  Suin Kim,et al.  Force-mode control of rotary series elastic actuators in a lower extremity exoskeleton using model-inverse time delay control (MiTDC) , 2016, 2016 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS).

[20]  S. Kolakowsky-Hayner,et al.  Safety and Feasibility of using the EksoTM Bionic Exoskeleton to Aid Ambulation after Spinal Cord Injury , 2013 .

[21]  Homayoon Kazerooni,et al.  Exoskeletons for human power augmentation , 2005, 2005 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[22]  Yoshiaki Hayashi,et al.  An EMG-Based Control for an Upper-Limb Power-Assist Exoskeleton Robot , 2012, IEEE Transactions on Systems, Man, and Cybernetics, Part B (Cybernetics).

[23]  Bernhard Schölkopf,et al.  Learning strategies in table tennis using inverse reinforcement learning , 2014, Biological Cybernetics.

[24]  Marcia Kilchenman O'Malley,et al.  An index finger exoskeleton with series elastic actuation for rehabilitation: Design, control and performance characterization , 2015, Int. J. Robotics Res..

[25]  Yassine Bouteraa,et al.  Exoskeleton robots for upper-limb rehabilitation , 2016, 2016 13th International Multi-Conference on Systems, Signals & Devices (SSD).

[26]  Zhijiang Du,et al.  Human Gait Trajectory Learning Using Online Gaussian Process for Assistive Lower Limb Exoskeleton , 2017 .

[27]  Alexander Ilin,et al.  Efficient Gaussian Process Inference for Short-Scale Spatio-Temporal Modeling , 2012, AISTATS.

[28]  Volker Tresp,et al.  A Bayesian Committee Machine , 2000, Neural Computation.

[29]  Masayoshi Tomizuka,et al.  Gait Phase-Based Control for a Rotary Series Elastic Actuator Assisting the Knee Joint , 2011 .

[30]  Marc Peter Deisenroth,et al.  Hierarchical Mixture-of-Experts Model for Large-Scale Gaussian Process Regression , 2014, ArXiv.

[31]  Léon Personnaz,et al.  Nonlinear internal model control using neural networks: application to processes with delay and design issues , 2000, IEEE Trans. Neural Networks Learn. Syst..

[32]  Tatsuo Narikiyo,et al.  Proof of Concept for Robot-Aided Upper Limb Rehabilitation Using Disturbance Observers , 2015, IEEE Transactions on Human-Machine Systems.

[33]  M. Morari,et al.  Internal model control: PID controller design , 1986 .

[34]  Grigore C. Burdea,et al.  The Rutgers Master II-new design force-feedback glove , 2002 .

[35]  Nevio Luigi Tagliamonte,et al.  Design and Characterization of a Novel High-Power Series Elastic Actuator for a Lower Limb Robotic Orthosis , 2013 .

[36]  Torsten Bumgarner,et al.  Biomechanics and Motor Control of Human Movement , 2013 .

[37]  A. Esquenazi,et al.  The ReWalk Powered Exoskeleton to Restore Ambulatory Function to Individuals with Thoracic-Level Motor-Complete Spinal Cord Injury , 2012, American journal of physical medicine & rehabilitation.

[38]  Ashish D. Deshpande,et al.  Series Elastic Actuators for Small-Scale Robotic Applications , 2017 .

[39]  Zhijiang Du,et al.  Development of a lower extremity wearable exoskeleton with double compact elastic module: preliminary experiments , 2017 .

[40]  R Jiménez-Fabián,et al.  Review of control algorithms for robotic ankle systems in lower-limb orthoses, prostheses, and exoskeletons. , 2012, Medical engineering & physics.

[41]  David J. Fleet,et al.  Generalized Product of Experts for Automatic and Principled Fusion of Gaussian Process Predictions , 2014, ArXiv.

[42]  David A. Winter,et al.  Biomechanics and Motor Control of Human Movement , 1990 .

[43]  M. Tomizuka,et al.  A Compact Rotary Series Elastic Actuator for Human Assistive Systems , 2012, IEEE/ASME Transactions on Mechatronics.

[44]  Michael R. Zinn,et al.  A New Actuation Approach for Human Friendly Robot Design , 2004, Int. J. Robotics Res..

[45]  Jus Kocijan,et al.  Control system with evolving Gaussian process models , 2011, 2011 IEEE Workshop on Evolving and Adaptive Intelligent Systems (EAIS).

[46]  Shiqian Wang,et al.  Design and Control of the MINDWALKER Exoskeleton , 2015, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[47]  Carl E. Rasmussen,et al.  Gaussian processes for machine learning , 2005, Adaptive computation and machine learning.

[48]  M. Tomizuka,et al.  Control of Rotary Series Elastic Actuator for Ideal Force-Mode Actuation in Human–Robot Interaction Applications , 2009, IEEE/ASME Transactions on Mechatronics.

[49]  M. Strintzis,et al.  CyberGrasp and PHANTOM Integration : Enhanced Haptic Access for Visually Impaired Users , 2004 .

[50]  Takamitsu Matsubara,et al.  Pneumatic artificial muscle-driven robot control using local update reinforcement learning , 2017, Adv. Robotics.

[51]  Shihua Li,et al.  Fuzzy Adaptive Internal Model Control Schemes for PMSM Speed-Regulation System , 2012, IEEE Transactions on Industrial Informatics.