Motion Planning of Upper-Limb Exoskeleton Robots: A Review

Clautilde, Nguiadem; Raison, Maxime; Achiche, Sofiane

doi:10.3390/app10217626

Cited by 29 publications

(8 citation statements)

References 69 publications

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“…Gopura et al [13] and Muhammad et al [14] comprehensively reviewed upper limb exoskeleton system designs and Rasedul et al [15] compared the research prototypes and commercial types of upper limbs. Some articles specifically performed literature reviews for key components for wearable upper limb robotics including mechanical designs [16], control strategies [17], actuation systems [18], and motion planning [19]. Most of these articles are for rigid exoskeletons.…”

Section: Introductionmentioning

confidence: 99%

Wearable upper limb robotics for pervasive health: a review

2023

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Wearable robotics, also called exoskeletons, have been engineered for human-centered assistance for decades. They provide assistive technologies for maintaining and improving patients’ natural capabilities towards self-independence and also enable new therapy solutions for rehabilitation towards pervasive health. Upper limb exoskeletons can significantly enhance human manipulation with environments, which is crucial to patients’ independence, self-esteem, and quality of life. For long-term use in both in-hospital and at-home settings, there are still needs for new technologies with high comfort, biocompatibility, and operability. The recent progress in soft robotics has initiated soft exoskeletons (also called exosuits), which are based on controllable and compliant materials and structures. Remarkable literature reviews have been performed for rigid exoskeletons ranging from robot design to different practical applications. Due to the emerging state, few have been focused on soft upper limb exoskeletons. This paper aims to provide a systematic review of the recent progress in wearable upper limb robotics including both rigid and soft exoskeletons with a focus on their designs and applications in various pervasive healthcare settings. The technical needs for wearable robots are carefully reviewed and the assistance and rehabilitation that can be enhanced by wearable robotics are particularly discussed. The knowledge from rigid wearable robots may provide practical experience and inspire new ideas for soft exoskeleton designs. We also discuss the challenges and opportunities of wearable assistive robotics for pervasive health.

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Section: Introductionmentioning

confidence: 99%

Wearable upper limb robotics for pervasive health: a review

2023

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“…Training strategies to relieve upper limb fatigue are developed and adjusted based on fatigue characteristics. As both the theory and technology of rehabilitation robots advance quickly, exoskeleton robots of upper limbs have become a major source of support for rehabilitation training, and they are widely used in therapies provided for patients with motion dysfunction [3]. Exoskeleton rehabilitation robots are primarily used to improve a patient's exercise capacity by expanding the range of motion of the upper limb joints.…”

Section: Introductionmentioning

confidence: 99%

Model for predicting the angles of upper limb joints in combination with sEMG and posture capture

Wang,

Xiang,

Zhi

et al. 2023

Meas. Sci. Technol.

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Since poor man–machine interaction and insufficient coupling occur in the processes of angle prediction and rehabilitation training based purely on the surface electromyography (sEMG) signal, a model for predicting the angles of upper limb joints was presented and validated by experiments. The sEMG and posture capture features were combined to build a hybrid vector, and the intentions of upper limb movements were characterized. The original signals were pre-treated with debiasing, filtering, and noise reduction, and then they were integrated to obtain signal characteristics. Then, feature values in the time domain, frequency domain, time-frequency domain, and entropy were extracted from the treated signals. The snake optimizer least squares support vector machine (SO-LSSVM) was modeled to predict the angles of upper limb joints to improve the poor precision and slow velocity of existing models in the movement control field. Experimental results showed that the prediction model performed well in predicting the motion trails of human upper limb joints from the sEMG signal and attitude information. It effectively reduced both skewing and error in prediction. Hence, it holds great promise for improving the man–machine coupling precision and velocity. Compared to the conventional LSSVM model, the proposed SO-LSSVM model reduced the training time, execution time, and root mean square error of evaluation parameters by 65%, 11%, and 76%, respectively. In summary, the proposed SO-LSSVM model satisfied the real-time requirement for rehabilitation robots and showed high accuracy and robustness.

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“…The recent technological advances that emerged in the last decade, including digital manufacturing and rapid prototyping, have boosted the development of these devices. Exoskeleton design requires careful attention to provide natural motion of the users without endangering their safety [4,5], which can be achieved by the application of biomimetic design methods [6].…”

Section: Introductionmentioning

confidence: 99%

Kinematic of the Position and Orientation Synchronization of the Posture of a n DoF Upper-Limb Exoskeleton with a Virtual Object in an Immersive Virtual Reality Environment

Huamanchahua¹,

Martínez²,

Ramirez‐Mendoza³

2021

Electronics

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Exoskeletons are an external structural mechanism with joints and links that work in tandem with the user, which increases, reinforces, or restores human performance. Virtual Reality can be used to produce environments, in which the intensity of practice and feedback on performance can be manipulated to provide tailored motor training. Will it be possible to combine both technologies and have them synchronized to reach better performance? This paper consists of the kinematics analysis for the position and orientation synchronization between an n DoF upper-limb exoskeleton pose and a projected object in an immersive virtual reality environment using a VR headset. To achieve this goal, the exoskeletal mechanism is analyzed using Euler angles and the Pieper technique to obtain the equations that lead to its orientation, forward, and inverse kinematic models. This paper extends the author’s previous work by using an early stage upper-limb exoskeleton prototype for the synchronization process.

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Motion Planning of Upper-Limb Exoskeleton Robots: A Review

Cited by 29 publications

References 69 publications

Wearable upper limb robotics for pervasive health: a review

Wearable upper limb robotics for pervasive health: a review

Model for predicting the angles of upper limb joints in combination with sEMG and posture capture

Kinematic of the Position and Orientation Synchronization of the Posture of a n DoF Upper-Limb Exoskeleton with a Virtual Object in an Immersive Virtual Reality Environment

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