Voluntary Control of an Ankle Joint Exoskeleton by Able-Bodied Individuals and Stroke Survivors using EMG-Based Admittance Control Scheme

Our objective in this study was to assess passive mechanical stiffness in the ankle of chronic hemiparetic stroke survivors and to compare it with those of healthy young and older (age-matched) individuals. Given the importance of the ankle during locomotion, an accurate estimate of passive ankle stiffness would be valuable for locomotor rehabilitation, potentially providing a measure of recovery and a quantitative basis to design treatment protocols. Using a novel ankle robot, we characterized passive ankle stiffness both in sagittal and in frontal planes by applying perturbations to the ankle joint over the entire range of motion with subjects in a relaxed state. We found that passive stiffness of the affected ankle joint was significantly higher in chronic stroke survivors than in healthy adults of a similar cohort, both in the sagittal as well as frontal plane of movement, in three out of four directions tested with indistinguishable stiffness values in plantarflexion direction. Our findings are comparable to the literature, thus indicating its plausibility, and, to our knowledge, report for the first time passive stiffness in the frontal plane for persons with chronic stroke and older healthy adults.

Download Full-text

Calibrating intuitive and natural human–robot interaction and performance for power-assisted heavy object manipulation using cognition-based intelligent admittance control schemes

International Journal of Advanced Robotic Systems ◽

10.1177/1729881418773190 ◽

2018 ◽

Vol 15 (4) ◽

pp. 172988141877319 ◽

Cited By ~ 3

Author(s):

S M Mizanoor Rahman ◽

Ryojun Ikeura

Keyword(s):

Predictive Control ◽

Optimization Algorithm ◽

Weight Perception ◽

Robotic System ◽

Human Robot Interaction ◽

Admittance Control ◽

Robot Interaction ◽

Heavy Object ◽

Control Scheme ◽

And Performance

In the first step, a one degree of freedom power assist robotic system is developed for lifting lightweight objects. Dynamics for human–robot co-manipulation is derived that includes human cognition, for example, weight perception. A novel admittance control scheme is derived using the weight perception–based dynamics. Human subjects lift a small-sized, lightweight object with the power assist robotic system. Human–robot interaction and system characteristics are analyzed. A comprehensive scheme is developed to evaluate the human–robot interaction and performance, and a constrained optimization algorithm is developed to determine the optimum human–robot interaction and performance. The results show that the inclusion of weight perception in the control helps achieve optimum human–robot interaction and performance for a set of hard constraints. In the second step, the same optimization algorithm and control scheme are used for lifting a heavy object with a multi-degree of freedom power assist robotic system. The results show that the human–robot interaction and performance for lifting the heavy object are not as good as that for lifting the lightweight object. Then, weight perception–based intelligent controls in the forms of model predictive control and vision-based variable admittance control are applied for lifting the heavy object. The results show that the intelligent controls enhance human–robot interaction and performance, help achieve optimum human–robot interaction and performance for a set of soft constraints, and produce similar human–robot interaction and performance as obtained for lifting the lightweight object. The human–robot interaction and performance for lifting the heavy object with power assist are treated as intuitive and natural because these are calibrated with those for lifting the lightweight object. The results also show that the variable admittance control outperforms the model predictive control. We also propose a method to adjust the variable admittance control for three degrees of freedom translational manipulation of heavy objects based on human intent recognition. The results are useful for developing controls of human friendly, high performance power assist robotic systems for heavy object manipulation in industries.

Download Full-text

Hybrid position/force control using an admittance control scheme in Cartesian space for a 3-DOF planar cable-driven parallel robot

International Journal of Control Automation and Systems ◽

10.1007/s12555-014-0538-x ◽

2016 ◽

Vol 14 (4) ◽

pp. 1106-1113 ◽

Cited By ~ 6

Author(s):

JongPyo Jun ◽

Xuemei Jin ◽

Andreas Pott ◽

Sukho Park ◽

Jong-Oh Park ◽

...

Keyword(s):

Force Control ◽

Parallel Robot ◽

Admittance Control ◽

Cartesian Space ◽

Control Scheme

Download Full-text

Unified Robot Control Scheme for Cooperative Motion, Autonomous Motion and Contact Reaction

Journal of Robotics and Mechatronics ◽

10.20965/jrm.2011.p0557 ◽

2011 ◽

Vol 23 (4) ◽

pp. 557-566 ◽

Cited By ~ 4

Author(s):

Vincent Duchaine ◽

◽

Clément Gosselin ◽

Keyword(s):

Robot Control ◽

Human Robot Interaction ◽

Future Generations ◽

Admittance Control ◽

Robot Interaction ◽

Modes Of Operation ◽

Cooperative Motion ◽

Control Scheme ◽

Industrial Manipulators ◽

Autonomous Motion

While the majority of industrial manipulators currently in use only need to performautonomousmotion, future generations of cooperative robots will also have to execute cooperative motion and intelligently react to contacts. These extended behaviours are essential to enable safe and effective physical Human-Robot Interaction (pHRI). However, they will inevitably result in an increase of the controller complexity. This paper presents a single variable admittance control scheme that handles the three modes of operation, thereby minimizing the complexity of the controller. First, the adaptative admittance controller previously proposed by the authors for cooperative motion is recalled. Then, a novel implementation of variable admittance control for the generation of smooth autonomous motion including reaction to collisions anywhere on the robot is presented. Finally, it is shown how the control equations for these three modes of operation can be simply unified into a unique control scheme.

Download Full-text

Operational Space Prescribed Tracking Performance and Compliance in Flexible Joint Robots

Journal of Dynamic Systems Measurement and Control ◽

10.1115/1.4029529 ◽

2015 ◽

Vol 137 (7) ◽

Cited By ~ 1

Author(s):

Abdelrahem Atawnih ◽

Zoe Doulgeri ◽

George A. Rovithakis

Keyword(s):

Degrees Of Freedom ◽

Position Tracking ◽

Admittance Control ◽

Flexible Joint ◽

Flexible Joint Robots ◽

Operational Space ◽

Control Scheme ◽

Simulation Results ◽

Flexible Joint Manipulator ◽

Three Degrees Of Freedom

In this work, an admittance control scheme is proposed utilizing a highly robust prescribed performance position tracking controller for flexible joint robots which is designed at the operational space. The proposed control scheme achieves the desired impedance to the external contact force as well as superior position tracking in free motion without any robot model knowledge, as opposed to the torque based impedance controllers. Comparative simulation results on a three degrees-of-freedom (3DOF) flexible joint manipulator, illustrate the efficiency of the approach.

Download Full-text