DYNAMIC MODELING AND EVALUATION OF A ROBOTIC EXOSKELETON FOR UPPER-LIMB REHABILITATION

Proper functioning of the shoulder, elbow, and wrist movements play a vital role in the performance of essential daily activities. To assist physically disabled people with impaired upper-limb function, we have been developing an exoskeleton robot (ExoRob) to rehabilitate and to ease upper limb motion. The proposed ExoRob will be comprised of seven degrees of freedom (DOFs) to enable natural movements of the human upper-limb. This paper focuses on the kinematic and dynamic modeling of the proposed ExoRob that corresponds to human upper-limbs. For this purpose, a nonlinear computed torque control technique was employed. In simulations, trajectory tracking corresponding to typical rehabilitation exercises were carried out to evaluate the performances of the developed model and controller. For the experimental part, only 3DOFs (elbow, wrist flexion/extension, wrist abduction/adduction) were considered. Simulated and experimental results show that the controller was able to maneuver the proposed ExoRob efficiently in order to track the desired trajectories, which in this case consisted in passive arm movements. Such movements are widely used in therapy and were performed efficiently with the developed ExoRob and the controller.

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Design and evaluation of a novel upper limb rehabilitation robot with space training based on an end effector

Mechanical Sciences ◽

10.5194/ms-12-639-2021 ◽

2021 ◽

Vol 12 (1) ◽

pp. 639-648

Author(s):

Qiaoling Meng ◽

Zongqi Jiao ◽

Hongliu Yu ◽

Weisheng Zhang

Keyword(s):

Upper Limb ◽

Degrees Of Freedom ◽

Elbow Flexion ◽

Rehabilitation Robot ◽

End Effector ◽

Upper Limb Rehabilitation ◽

Flexion Extension ◽

Robot Configuration ◽

Limb Rehabilitation ◽

Equivalent Mechanism

Abstract. The target of this paper is to design a lightweight upper limb rehabilitation robot with space training based on end-effector configuration and to evaluate the performance of the proposed mechanism. In order to implement this purpose, an equivalent mechanism to the human being upper limb is proposed before the design. Then, a 4 degrees of freedom (DOF) end-effector-based upper limb rehabilitation robot configuration is designed to help stroke patients perform space rehabilitation training of the shoulder flexion/extension and adduction/abduction and elbow flexion/extension. Thereafter, its kinematical model is established together with the proposed equivalent upper limb mechanism. The Monte Carlo method is employed to establish their workspace. The results show that the overlap of the workspace between the proposed mechanism and the equivalent mechanism is 96.61 %. In addition, this paper also constructs a human–machine closed-chain mechanism to analyze the flexibility of the mechanism. According to the relative manipulability and manipulability ellipsoid, the highly flexible area of the mechanism accounts for 67.6 %, and the mechanism is far away from the singularity on the drinking trajectory. In the end, the single-joint training experiments and a drinking water training trajectory planning experiment are developed and the prototype is manufactured to verify it.

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ARMin III – Arm Therapy Exoskeleton with an Ergonomic Shoulder Actuation

Applied Bionics and Biomechanics ◽

10.1155/2009/962956 ◽

2009 ◽

Vol 6 (2) ◽

pp. 127-142 ◽

Cited By ~ 181

Author(s):

Tobias Nef ◽

Marco Guidali ◽

Robert Riener

Keyword(s):

Degrees Of Freedom ◽

The United States ◽

Rehabilitation Robotics ◽

The Body ◽

Wrist Flexion ◽

Upper Limb Rehabilitation ◽

Rehabilitation Robots ◽

Human Arm ◽

Flexion Extension ◽

Limb Rehabilitation

Rehabilitation robots have become important tools in stroke rehabilitation. Compared to manual arm training, robot-supported training can be more intensive, of longer duration and more repetitive. Therefore, robots have the potential to improve the rehabilitation process in stroke patients. Whereas a majority of previous work in upper limb rehabilitation robotics has focused on end-effector-based robots, a shift towards exoskeleton robots is taking place because they offer a better guidance of the human arm, especially for movements with a large range of motion. However, the implementation of an exoskeleton device introduces the challenge of reproducing the motion of the human shoulder, which is one of the most complex joints of the body. Thus, this paper starts with describing a simplified model of the human shoulder. On the basis of that model, a new ergonomic shoulder actuation principle that provides motion of the humerus head is proposed, and its implementation in the ARMin III arm therapy robot is described. The focus lies on the mechanics and actuation principle. The ARMin III robot provides three actuated degrees of freedom for the shoulder and one for the elbow joint. An additional module provides actuated lower arm pro/supination and wrist flexion/extension. Five ARMin III devices have been manufactured and they are currently undergoing clinical evaluation in hospitals in Switzerland and in the United States.

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A 4-DOF Upper Limb Exoskeleton for Physical Assistance: Design, Modeling, Control and Performance Evaluation

Applied Sciences ◽

10.3390/app11135865 ◽

2021 ◽

Vol 11 (13) ◽

pp. 5865

Author(s):

Muhammad Ahsan Gull ◽

Mikkel Thoegersen ◽

Stefan Hein Bengtson ◽

Mostafa Mohammadi ◽

Lotte N. S. Andreasen Struijk ◽

...

Keyword(s):

Upper Limb ◽

Tracking Control ◽

Degrees Of Freedom ◽

Control Method ◽

Mechanical Design ◽

Trajectory Tracking Control ◽

Upper Limb Exoskeleton ◽

And Performance ◽

Physically Disabled People ◽

Human Upper Limb

Wheelchair mounted upper limb exoskeletons offer an alternative way to support disabled individuals in their activities of daily living (ADL). Key challenges in exoskeleton technology include innovative mechanical design and implementation of a control method that can assure a safe and comfortable interaction between the human upper limb and exoskeleton. In this article, we present a mechanical design of a four degrees of freedom (DOF) wheelchair mounted upper limb exoskeleton. The design takes advantage of non-backdrivable mechanism that can hold the output position without energy consumption and provide assistance to the completely paralyzed users. Moreover, a PD-based trajectory tracking control is implemented to enhance the performance of human exoskeleton system for two different tasks. Preliminary results are provided to show the effectiveness and reliability of using the proposed design for physically disabled people.

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Design and Development of an Upper Limb Rehabilitative Robot with Dual Functionality

Micromachines ◽

10.3390/mi12080870 ◽

2021 ◽

Vol 12 (8) ◽

pp. 870

Author(s):

Md Rasedul Islam ◽

Md Assad-Uz-Zaman ◽

Brahim Brahmi ◽

Yassine Bouteraa ◽

Inga Wang ◽

...

Keyword(s):

Upper Limb ◽

Research Work ◽

Human Robot Interaction ◽

Control Technique ◽

Upper Arm ◽

Interaction Forces ◽

End Effector ◽

Upper Limb Rehabilitation ◽

End Point ◽

Limb Rehabilitation

The design of an upper limb rehabilitation robot for post-stroke patients is considered a benchmark problem regarding improving functionality and ensuring better human–robot interaction (HRI). Existing upper limb robots perform either joint-based exercises (exoskeleton-type functionality) or end-point exercises (end-effector-type functionality). Patients may need both kinds of exercises, depending on the type, level, and degree of impairments. This work focused on designing and developing a seven-degrees-of-freedom (DoFs) upper-limb rehabilitation exoskeleton called ‘u-Rob’ that functions as both exoskeleton and end-effector types device. Furthermore, HRI can be improved by monitoring the interaction forces between the robot and the wearer. Existing upper limb robots lack the ability to monitor interaction forces during passive rehabilitation exercises; measuring upper arm forces is also absent in the existing devices. This research work aimed to develop an innovative sensorized upper arm cuff to measure the wearer’s interaction forces in the upper arm. A PID control technique was implemented for both joint-based and end-point exercises. The experimental results validated both types of functionality of the developed robot.

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CONTROL OF FOREARM MODULE IN UPPER-LIMB REHABILITATION ROBOT FOR REDUCTION AND BIOMECHANICAL ASSESSMENT OF PRONATOR HYPERTONIA OF STROKE PATIENTS

Journal of Mechanics in Medicine and Biology ◽

10.1142/s0219519416500081 ◽

2016 ◽

Vol 16 (02) ◽

pp. 1650008 ◽

Cited By ~ 4

Author(s):

PIN-CHENG KUNG ◽

CHOU-CHING K. LIN ◽

SHU-MIN CHEN ◽

MING-SHAUNG JU

Keyword(s):

Upper Limb ◽

Position Control ◽

Biomechanical Properties ◽

Torque Control ◽

Rehabilitation Robot ◽

Stroke Patients ◽

Upper Limb Rehabilitation ◽

Biomechanical Assessment ◽

Custom Made ◽

Limb Rehabilitation

Spastic hypertonia causes loss of range of motion (ROM) and contractures in patients with post-stroke hemiparesis. The pronation/supination of the forearm is an essential functional movement in daily activities. We developed a special module for a shoulder-elbow rehabilitation robot for the reduction and biomechanical assessment of pronator/supinator hypertonia of the forearm. The module consisted of a rotational drum driven by an AC servo motor and equipped with an encoder and a custom-made torque sensor. By properly switching the control algorithm between position control and torque control, a hybrid controller able to mimic a therapist’s manual stretching movements was designed. Nine stroke patients were recruited to validate the functions of the module. The results showed that the affected forearms had significant increases in the ROM after five cycles of stretching. Both the passive ROM and the average stiffness were highly correlated to the spasticity of the forearm flexor muscles as measured using the Modified Ashworth Scale (MAS). With the custom-made module and controller, this upper-limb rehabilitation robot may be able to aid physical therapists to reduce hypertonia and quantify biomechanical properties of the muscles for forearm rotation in stroke patients.

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Non-linear active disturbance rejection control for upper limb rehabilitation exoskeleton

Proceedings of the Institution of Mechanical Engineers Part I Journal of Systems and Control Engineering ◽

10.1177/0959651820954575 ◽

2020 ◽

pp. 095965182095457

Author(s):

Sumit Aole ◽

Irraivan Elamvazuthi ◽

Laxman Waghmare ◽

Balasaheb Patre ◽

Fabrice Meriaudeau

Keyword(s):

Upper Limb ◽

Trajectory Tracking ◽

Disturbance Rejection ◽

Active Disturbance Rejection Control ◽

Upper Limb Rehabilitation ◽

Active Disturbance Rejection ◽

Disturbance Rejection Control ◽

Flexion Extension ◽

Non Linear ◽

Limb Rehabilitation

Trajectory tracking in upper limb rehabilitation exercises is utilized for repeatability of joint movement to improve the patient’s recovery in the early stages of rehabilitation. In this article, non-linear active disturbance rejection control as a combination of non-linear extended-state observer and non-linear state error feedback is used for the sinusoidal trajectory tracking control of the two-link model of an upper limb rehabilitation exoskeleton. The two links represent movements like flexion/extension for both the shoulder joint and the elbow joint in the sagittal plane. The Euler–Lagrange method was employed to acquire a dynamic model of an upper limb rehabilitation exoskeleton. To examine the efficacy and robustness of the proposed method, four disturbances cases in simulation studies with 20% parameter variation were applied. It was found that the non-linear active disturbance rejection control is robust against disturbances and achieves better tracking as compared to proportional–integral–derivative and existing conventional active disturbance rejection control method.

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Diseño mecánico de un exoesqueleto para rehabilitación de miembro superior

Revista Colombiana de Biotecnología ◽

10.15446/rev.colomb.biote.v17n1.44188 ◽

2015 ◽

Vol 17 (1) ◽

pp. 79-90 ◽

Cited By ~ 2

Author(s):

Juan Francisco Ayala Lozano ◽

Guillermo Urriolagoitia Sosa ◽

Beatriz Romero Ángeles ◽

Christopher René Torres San-Miguel ◽

Luis Antonio Aguilar-Pérez ◽

...

Keyword(s):

Upper Limb ◽

Degrees Of Freedom ◽

Mechanical Design ◽

Low Cost ◽

Structure Design ◽

Upper Limb Rehabilitation ◽

Palabras Clave ◽

Mexican Patient ◽

Almost All ◽

Limb Rehabilitation

Título en ingles: Mechanical design of an exoskeleton for upper limb rehabilitationTítulo corto: Diseño mecánico de un exoesqueletoResumen: El ritmo de vida actual, tanto sociocultural como tecnológico, ha desembocado en un aumento de enfermedades y padecimientos que afectan las capacidades físico-motrices de los individuos. Esto ha originado el desarrollo de prototipos para auxiliar al paciente a recuperar la movilidad y la fortaleza de las extremidades superiores afectadas. El presente trabajo aborda el diseño de una estructura mecánica de un exoesqueleto con 4 grados de libertad para miembro superior. La cual tiene como principales atributos la capacidad de ajustarse a la antropometría del paciente mexicano (longitud del brazo, extensión del antebrazo, condiciones geométricas de la espalda y altura del paciente). Se aplicó el método BLITZ QFD para obtener el diseño conceptual óptimo y establecer adecuadamente las condiciones de carga de servicio. Por lo que, se definieron 5 casos de estudio cuasi-estáticos e implantaron condiciones para rehabilitación de los pacientes. Asimismo, mediante el Método de Elemento Finito (MEF) se analizaron los esfuerzos y deformaciones a los que la estructura está sometida durante la aplicación de los agentes externos de servicio. Los resultados presentados en éste trabajo exhiben una nueva propuesta para la rehabilitación de pacientes con problemas de movilidad en miembro superior. Donde el equipo propuesto permite la rehabilitación del miembro superior apoyado en 4 grados de libertad (tres grados de libertad en el hombro y uno en el codo), el cual es adecuado para realizar terapias activas y pasivas. Asimismo, es un dispositivo que está al alcance de un mayor porcentaje de la población por su bajo costo y fácil desarrollo en la fabricación.Palabras clave: MEF, Blitz QFD, exoesqueletos, diseño mecánico.Abstract: The pace of modern life, both socio-cultural and technologically, has led to an increase of diseases and conditions that affect the physical-motor capabilities of persons. This increase has originated the development of prototypes to help patients to regain mobility and strength of the affected upper limb. This work, deals with the mechanical structure design of an exoskeleton with 4 degrees freedom for upper limb. Which has the capacity to adjust to the Mexican patient anthropometry (arm length, forearm extension, geometry conditions of the back and the patient’s height) BLITZ QFD method was applied to establish the conceptual design and loading service conditions on the structure. So, 5 quasi-static cases of study were defined and conditions for patient rehabilitation were subjected. Also by applying the finite element method the structure was analyzed due to service loading. The results presented in this work, show a new method for patient rehabilitation with mobility deficiencies in the upper limb. The proposed new design allows the rehabilitation of the upper limb under 4 degrees of freedom (tree degrees of freedom at shoulder and one at the elbow), which is perfect to perform active and passive therapy. Additionally, it is an equipment of low cost, which can be affordable to almost all the country population.Key words: FEM, Blitz QFD, exoskeletons, mechanical design.Recibido: agosto 20 de 2014 Aprobado: marzo 26 de 2015

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Design of Shape Memory Alloy-Based Soft Wearable Robot for Assisting Wrist Motion

Applied Sciences ◽

10.3390/app9194025 ◽

2019 ◽

Vol 9 (19) ◽

pp. 4025 ◽

Cited By ~ 1

Author(s):

Jaeyeon Jeong ◽

Ibrahim Bin Yasir ◽

Jungwoo Han ◽

Cheol Hoon Park ◽

Soo-Kyung Bok ◽

...

Keyword(s):

Shape Memory Alloy ◽

Shape Memory ◽

Degrees Of Freedom ◽

Wrist Flexion ◽

Wearable Robot ◽

Maximum Torque ◽

Wrist Motion ◽

Contraction Ratio ◽

Flexion Extension ◽

The Average Range

In this paper, we propose a shape memory alloy (SMA)-based wearable robot that assists the wrist motion for patients who have difficulties in manipulating the lower arm. Since SMA shows high contraction strain when it is designed as a form of coil spring shape, the proposed muscle-like actuator was designed after optimizing the spring parameters. The fabricated actuator shows a maximum force of 10 N and a maximum contraction ratio of 40%. The SMA-based wearable robot, named soft wrist assist (SWA), assists 2 degrees of freedom (DOF) wrist motions. In addition, the robot is totally flexible and weighs 151g for the wearable parts. A maximum torque of 1.32 Nm was measured for wrist flexion, and a torque of larger than 0.5 Nm was measured for the other motions. The robot showed the average range of motion (ROM) with 33.8, 30.4, 15.4, and 21.4 degrees for flexion, extension, ulnar, and radial deviation, respectively. Thanks to the soft feature of the SWA, time cost for wearing the device is shorter than 2 min as was also the case for patients when putting it on by themselves. From the experimental results, the SWA is expected to support wrist motion for diverse activities of daily living (ADL) routinely for patients.

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Functional Reorganization in Chronic Hemiparetic Patients after Training: fMRI Studies

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.321-323.1016 ◽

2006 ◽

Vol 321-323 ◽

pp. 1016-1021

Author(s):

Ki Sik Tae ◽

Sung Jae Song ◽

So Young Lee ◽

Gi Young Park ◽

Chul Ho Sohn ◽

...

Keyword(s):

Training Program ◽

Upper Limb ◽

Hand Movement ◽

Active Movement ◽

Wrist Flexion ◽

Motor Tasks ◽

Neural Basis ◽

Motor Network ◽

Flexion Extension ◽

Before And After

The aim of this study was to evaluate effects of short-term repetitive-bilateral exercise on the activation of motor network using functional magnetic resonance imaging (fMRI). Eight control subjects and four chronic hemiparetic patients were investigated for the present study. The training program with a symmetrical upper-limb motion trainer was performed at 1 hr/day, 5 days/week during 6 weeks. Fugl-Meyer assessments (FMA) were performed every two weeks during the training. We compared cerebral and cerebellar cortical activations in two different tasks before and after the training program: (1) the only unaffected hand movement (Task 1), and (2) passive movements of the affected hand by the active movement of the unaffected hand (Task 2). fMRI was performed at 3T with wrist flexion-extension movement at 1 Hz during the motor tasks. All patients showed significant improvements of FMA scores in their paretic limbs after training. fMRI studies in Task 1 showed that cortical activations decreased in ipsilateral SMC but increased in contralateral sensorimotor cortex (SMC) and ipsilateral cerebellum (CRB). Task 2 showed cortical reorganizations in bilateral SMC, pre-motor area (PMA), supplementary area (SMA) and CRB. This study demonstrated that plastic changes of motor network occurred as a neural basis of the improvement subsequent to repetitive-bilateral exercises using the symmetrical upper-limb motion trainer.

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Development of a whole arm wearable robotic exoskeleton for rehabilitation and to assist upper limb movements

Robotica ◽

10.1017/s0263574714000034 ◽

2014 ◽

Vol 33 (1) ◽

pp. 19-39 ◽

Cited By ~ 79

Author(s):

M. H. Rahman ◽

M. J. Rahman ◽

O. L. Cristobal ◽

M. Saad ◽

J. P. Kenné ◽

...

Keyword(s):

Upper Limb ◽

Wrist Joint ◽

External Rotation ◽

Lateral Side ◽

Limb Movements ◽

Rehabilitation Therapy ◽

Robotic Exoskeleton ◽

Flexion Extension ◽

Upper Limb Movements ◽

Physically Disabled People

SUMMARYTo assist physically disabled people with impaired upper limb function, we have developed a new 7-DOF exoskeleton-type robot named Motion Assistive Robotic-Exoskeleton for Superior Extremity (ETS-MARSE) to ease daily upper limb movements and to provide effective rehabilitation therapy to the superior extremity. The ETS-MARSE comprises a shoulder motion support part, an elbow and forearm motion support part, and a wrist motion support part. It is designed to be worn on the lateral side of the upper limb in order to provide naturalistic movements of the shoulder (vertical and horizontal flexion/extension and internal/external rotation), elbow (flexion/extension), forearm (pronation/supination), and wrist joint (radial/ulnar deviation and flexion/extension). This paper focuses on the modeling, design, development, and control of the ETS-MARSE. Experiments were carried out with healthy male human subjects in whom trajectory tracking in the form of passive rehabilitation exercises (i.e., pre-programmed trajectories recommended by a therapist/clinician) were carried out. Experimental results show that the ETS-MARSE can efficiently perform passive rehabilitation therapy.

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