Hybrid Active Control With Human Intention Detection of an Upper-Limb Cable-Driven Rehabilitation Robot

Rehabilitation robots play an increasingly important role in the recovery of motor function for stroke. To ensure a natural physical human-robot interaction (pHRI) and enhance the active participation of subjects, it is necessary for the robots to understand the human intention and cooperate actively with humanlike characteristics. This study proposed a hybrid active control algorithm with human motion intention detection. The motion intention was defined as the desired position and velocity, which were continuously estimated according to the human upper-limb model and minimum jerk model, respectively. The motion intention was then fed into a hybrid force and position controller of an upper-limb cable driven rehabilitation robot (CDRR). And a three-dimensional reaching task without predefined trajectory was employed to validate the effectiveness of the proposed control algorithm. Experimental results showed that the control algorithm could continuously recognize the human motion intention and enabled the robot better movement performance indicated as smaller offset error, smoother trajectory, and lower impact. The proposed method could guarantee a natural pHRI and improve the engagement of the subjects, which has great potential in clinical applications.

[1]  Andrew McDaid,et al.  Adaptive Trajectory Tracking Control of a Parallel Ankle Rehabilitation Robot With Joint-Space Force Distribution , 2019, IEEE Access.

[2]  Jake J. Abbott,et al.  Human Velocity Control of Admittance-Type Robotic Devices With Scaled Visual Feedback of Device Motion , 2016, IEEE Transactions on Human-Machine Systems.

[3]  Hyouk Ryeol Choi,et al.  Variable Admittance Control of Robot Manipulators Based on Human Intention , 2019, IEEE/ASME Transactions on Mechatronics.

[4]  Hamid D. Taghirad,et al.  An Analytic-Iterative Redundancy Resolution Scheme for Cable-Driven Redundant Parallel Manipulators , 2011, IEEE Transactions on Robotics.

[5]  John Kenneth Salisbury,et al.  Stability of Haptic Rendering: Discretization, Quantization, Time Delay, and Coulomb Effects , 2006, IEEE Transactions on Robotics.

[6]  D. Reinkensmeyer,et al.  Review of control strategies for robotic movement training after neurologic injury , 2009, Journal of NeuroEngineering and Rehabilitation.

[7]  Hsieh-Yu Li,et al.  A Control Scheme for Physical Human-Robot Interaction Coupled with an Environment of Unknown Stiffness , 2020, J. Intell. Robotic Syst..

[8]  Jun Morimoto,et al.  Adaptive Control of Exoskeleton Robots for Periodic Assistive Behaviours Based on EMG Feedback Minimisation , 2016, PloS one.

[9]  T. Flash,et al.  The coordination of arm movements: an experimentally confirmed mathematical model , 1985, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[10]  Jian Huang,et al.  Control of Upper-Limb Power-Assist Exoskeleton Using a Human-Robot Interface Based on Motion Intention Recognition , 2015, IEEE Transactions on Automation Science and Engineering.

[11]  Xiang Huang,et al.  Posture adjustment method for large components of aircraft based on hybrid force-position control , 2020, Ind. Robot.

[12]  Chenguang Yang,et al.  Neural Networks Enhanced Adaptive Admittance Control of Optimized Robot–Environment Interaction , 2019, IEEE Transactions on Cybernetics.

[13]  Yuehong Yin,et al.  Gaussian Process-Integrated State Space Model for Continuous Joint Angle Prediction from EMG and Interactive Force in a Human-Exoskeleton System , 2019, Applied Sciences.

[14]  Juan Antonio Corrales,et al.  Predicting Human Intent for Cooperative Physical Human-Robot Interaction Tasks , 2019, 2019 IEEE 15th International Conference on Control and Automation (ICCA).

[15]  C. Burgar,et al.  Robot-assisted movement training compared with conventional therapy techniques for the rehabilitation of upper-limb motor function after stroke. , 2002, Archives of physical medicine and rehabilitation.

[16]  Hualiang Zhang,et al.  Frequency-division based hybrid force/position control of robotic arms manipulating in uncertain environments , 2020, Ind. Robot.

[17]  Chenguang Yang,et al.  Robot Learning System Based on Adaptive Neural Control and Dynamic Movement Primitives , 2019, IEEE Transactions on Neural Networks and Learning Systems.

[18]  Mustafa Sinasi Ayas,et al.  Fuzzy logic based adaptive admittance control of a redundantly actuated ankle rehabilitation robot , 2017 .

[19]  Sohrab Khanmohammadi,et al.  A soft robotics nonlinear hybrid position/force control for tendon driven catheters , 2017 .

[20]  Xiaoyun Wang,et al.  Sliding Mode Tracking Control of a Wire-Driven Upper-Limb Rehabilitation Robot with Nonlinear Disturbance Observer , 2017, Front. Neurol..

[21]  Rong Song,et al.  Admittance Control Based on EMG-Driven Musculoskeletal Model Improves the Human–Robot Synchronization , 2019, IEEE Transactions on Industrial Informatics.

[22]  Shuzhi Sam Ge,et al.  Human–Robot Collaboration Based on Motion Intention Estimation , 2014, IEEE/ASME Transactions on Mechatronics.

[23]  Tetsuo Tomiyama,et al.  Human-Intent Detection and Physically Interactive Control of a Robot Without Force Sensors , 2010, IEEE Transactions on Robotics.

[24]  Jane L. Woodward,et al.  Contributions of Stepping Intensity and Variability to Mobility in Individuals Poststroke. , 2019, Stroke.

[25]  Robert Riener,et al.  Transferring ARMin to the Clinics and Industry , 2011 .

[26]  Herman van der Kooij,et al.  LIMPACT:A Hydraulically Powered Self-Aligning Upper Limb Exoskeleton , 2015, IEEE/ASME Transactions on Mechatronics.

[27]  Neville Hogan,et al.  Impedance control - An approach to manipulation. I - Theory. II - Implementation. III - Applications , 1985 .

[28]  Dylan P. Losey,et al.  Trajectory Deformations From Physical Human–Robot Interaction , 2017, IEEE Transactions on Robotics.

[29]  Marcia K. O'Malley,et al.  Learning the Correct Robot Trajectory in Real-Time from Physical Human Interactions , 2019, ACM Transactions on Human-Robot Interaction.

[30]  P LoseyDylan,et al.  Learning the Correct Robot Trajectory in Real-Time from Physical Human Interactions , 2020 .

[31]  Rong Song,et al.  Kinematic Outcome Measures using Target-Reaching Arm Movement in Stroke , 2017, Annals of Biomedical Engineering.

[32]  Clément Gosselin,et al.  An admittance control scheme for haptic interfaces based on cable-driven parallel mechanisms , 2014, 2014 IEEE International Conference on Robotics and Automation (ICRA).

[33]  Marc Gouttefarde,et al.  Redundancy Resolution Integrated Model Predictive Control of CDPRs: Concept, Implementation and Experiments , 2020, 2020 IEEE International Conference on Robotics and Automation (ICRA).

[34]  J.C. Perry,et al.  Upper-Limb Powered Exoskeleton Design , 2007, IEEE/ASME Transactions on Mechatronics.

[35]  Farshid Amirabdollahian,et al.  Training modalities in robot-mediated upper limb rehabilitation in stroke: a framework for classification based on a systematic review , 2014, Journal of NeuroEngineering and Rehabilitation.

[36]  Robert Riener,et al.  A novel paradigm for patient-cooperative control of upper-limb rehabilitation robots , 2007, Adv. Robotics.

[37]  Hongxu Ma,et al.  Real-Time Human Intention Recognition of Multi-Joints Based on MYO , 2020, IEEE Access.

[38]  Dagmar Sternad,et al.  Sensitivity of Smoothness Measures to Movement Duration, Amplitude, and Arrests , 2009, Journal of motor behavior.

[39]  Fares Alahdab,et al.  Global, regional, and national burden of stroke, 1990–2016: a systematic analysis for the Global Burden of Disease Study 2016 , 2019, The Lancet Neurology.

[40]  Grant D. Huang,et al.  Robot-assisted therapy for long-term upper-limb impairment after stroke. , 2010, The New England journal of medicine.

[41]  Agnes Roby-Brami,et al.  Upper-Limb Robotic Exoskeletons for Neurorehabilitation: A Review on Control Strategies , 2016, IEEE Reviews in Biomedical Engineering.

[42]  Andreas Pott,et al.  Hybrid position/force control using an admittance control scheme in Cartesian space for a 3-DOF planar cable-driven parallel robot , 2016, International Journal of Control, Automation and Systems.

[43]  Hermano I Krebs,et al.  Rehabilitation robotics: pilot trial of a spatial extension for MIT-Manus , 2004, Journal of NeuroEngineering and Rehabilitation.

[44]  Alessandro Di Nuovo,et al.  A Framework of Hybrid Force/Motion Skills Learning for Robots , 2020, IEEE Transactions on Cognitive and Developmental Systems.

[45]  Dimitrios Papageorgiou,et al.  Reaching for redundant arms with human-like motion and compliance properties , 2014, Robotics Auton. Syst..

[46]  Edoardo Battaglia,et al.  A Review of Intent Detection, Arbitration, and Communication Aspects of Shared Control for Physical Human-Robot Interaction , 2018 .