Design and Kinematics Analysis of Parallel Robots for Ankle Rehabilitation

Liu, Gengqian; Gao, Jinlian; Yue, Hong; Zhang, Xiaojun; Lu, Guangda

doi:10.1109/iros.2006.281710

Cited by 50 publications

(38 citation statements)

References 6 publications

(5 reference statements)

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“…Unlike the Stewart platform-based design, the degrees of freedom (DoF) of this device match those of the human ankle and a center strut is employed in the kinematics to achieve high structural stiffness. Spherical 3RSS/S 1 (Liu et al 2006) and Agile Eye (spherical 3RRR) (Malosio et al 2014) mechanisms have also been used for ankle rehabilitation. These devices possess good load carrying capacities with compact designs.…”

Section: Robot-assisted Ankle Rehabilitationmentioning

confidence: 99%

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Assist On-Ankle: a reconfigurable ankle exoskeleton with series-elastic actuation

et al. 2016

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We present the kinematics, optimal dimensional synthesis, series-elastic actuation, control, characterization and user evaluation of AssistOn-Ankle, a reconfigurable, powered exoskeleton for ankle rehabilitation. AssistOnAnkle features reconfigurable kinematics for delivery of both range of motion (RoM)/strengthening and balance/ proprioception exercises. In particular, through lockable joints, the underlying kinematics can be configured to either a self-aligning parallel mechanism that can naturally cover the whole RoM of the human ankle, or another parallel mechanism that can support the ground reaction forces/torques transferred to the ankle. Utilizing a single device to treat multiple phases of treatment is advantageous for robotic rehabilitation, since not only does it decrease the device cost and help with the space requirements, but also shorten the time it takes for patients to familiarize with the device. Bowden cable-based series-elastic actuation of AssistOn-Ankle allows for a remote placement of the motors/drivers to result in a compact design with low apparent inertia, while also enabling high-fidelity force/impedance control and active backdriveability of the device. This is one of several papers published in Autonomous Robots comprising the "Special Issue on Assistive and Rehabilitation Robotics". B Volkan Patoglu

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Section: Robot-assisted Ankle Rehabilitationmentioning

confidence: 99%

“…These devices possess good load carrying capacities with compact designs. 3RSS/S mechanism in Liu et al (2006) relies on force sensors for the control, while a smooth motion control, based on a minimum jerk reference trajectory, validated through EMG measurements, is used for the control of the Agile Eye mechanism.…”

Section: Robot-assisted Ankle Rehabilitationmentioning

confidence: 99%

Assist On-Ankle: a reconfigurable ankle exoskeleton with series-elastic actuation

et al. 2016

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“…Rutgers University developed a 6-DOF ankle rehabilitation robot “Rutgers ankle” based on a Stewart platform driven by pneumatic actuation, where a 6-DOF force sensor was used to provide force and torque feedback generated between the patient's foot and the foot pedal [5]. Liu et al announced a 3-RSS/S parallel robotic platform associated with a virtual training environment, which employed servo motor to drive its parallel links [6]. Meng et al constructed a parallel structure ankle rehabilitation robot, where the patient's leg is fixed to the base of the robot; therefore, the robot can drive the patient's foot to generate relative movement using the ankle joint as the pivot center [7].…”

Section: Introductionmentioning

confidence: 99%

Development of a New Robotic Ankle Rehabilitation Platform for Hemiplegic Patients after Stroke

Liu

Long

Sun

et al. 2018

Journal of Healthcare Engineering

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A large amount of hemiplegic survivors are suffering from motor impairment. Ankle rehabilitation exercises act an important role in recovering patients' walking ability after stroke. Currently, patients mainly perform ankle exercise to reobtain range of motion (ROM) and strength of the ankle joint under a therapist's assistance by manual operation. However, therapists suffer from high work intensity, and most of the existed rehabilitation devices focus on ankle functional training and ignore the importance of neurological rehabilitation in the early hemiplegic stage. In this paper, a new robotic ankle rehabilitation platform (RARP) is proposed to assist patients in executing ankle exercise. The robotic platform consists of two three-DOF symmetric layer-stacking mechanisms, which can execute ankle internal/external rotation, dorsiflexion/plantarflexion, and inversion/eversion exercise while the rotation center of the distal zone of the robotic platform always coincides with patients' ankle pivot center. Three exercise modes including constant-speed exercise, constant torque-impedance exercise, and awareness exercise are developed to execute ankle training corresponding to different rehabilitation stages. Experiments corresponding to these three ankle exercise modes are performed, the result demonstrated that the RARP is capable of executing ankle rehabilitation, and the novel awareness exercise mode motivates patients to proactively participate in ankle training.

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“…To develop the robotic devices, first the motor learning and motor adaption of healthy people should be investigated; and then the neurologically injured patients can be rehabilitated with respect to the obtained results [ 22 , 23 ]. Therapeutic exercises can vary from range of motion, active assistive isotonic, isometric, isokinetic, and manual exercises [ 24 – 26 ].…”

Section: Introductionmentioning

confidence: 99%

Parallel Robot for Lower Limb Rehabilitation Exercises

Rastegarpanah

Saadat

Borboni

2016

Applied Bionics and Biomechanics

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The aim of this study is to investigate the capability of a 6-DoF parallel robot to perform various rehabilitation exercises. The foot trajectories of twenty healthy participants have been measured by a Vicon system during the performing of four different exercises. Based on the kinematics and dynamics of a parallel robot, a MATLAB program was developed in order to calculate the length of the actuators, the actuators' forces, workspace, and singularity locus of the robot during the performing of the exercises. The calculated length of the actuators and the actuators' forces were used by motion analysis in SolidWorks in order to simulate different foot trajectories by the CAD model of the robot. A physical parallel robot prototype was built in order to simulate and execute the foot trajectories of the participants. Kinect camera was used to track the motion of the leg's model placed on the robot. The results demonstrate the robot's capability to perform a full range of various rehabilitation exercises.

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Design and Kinematics Analysis of Parallel Robots for Ankle Rehabilitation

Cited by 50 publications

References 6 publications

Assist On-Ankle: a reconfigurable ankle exoskeleton with series-elastic actuation

Assist On-Ankle: a reconfigurable ankle exoskeleton with series-elastic actuation

Development of a New Robotic Ankle Rehabilitation Platform for Hemiplegic Patients after Stroke

Parallel Robot for Lower Limb Rehabilitation Exercises

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