Soft-amphibious robot using thin and soft McKibben actuator

Faudzi, A. A. M.; Razif, Muhammad Rusydi Muhammad; Endo, Gen; Nabae, Hiroyuki; Suzumori, Koichi

doi:10.1109/aim.2017.8014146

Cited by 32 publications

(22 citation statements)

References 17 publications

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“…We developed flimsy delicate McKibben muscles for large-scale manufacturing created by Takaoka et al (2013). The muscles are light, little, and appropriate for straightforward frameworks as clarified by Faudzi et al (2017).…”

Section: Literature Reviewmentioning

confidence: 99%

Development of soft actuators for stroke rehabilitation using deep learning

Alshammari¹

2021

Int. j. adv. appl. sci.

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Automation has created a mind-blowing impact in diversified fields all over the world. Not only in business but also in various domains like health care sectors, manufacturing, etc. a faultless execution is a prime concern. Robotic Process Automation has paved the way for research in the mechanical and mechatronics field. Software robots are trained well to complete repetitive tasks in an efficient manner. A design of such a soft robot can be greatly helpful in the arena of healing. Automation of Rehabilitation therapy has gained attention in recent years. The main aspiration towards the conduct of this research work is to accomplish a soft exoskeleton robot using a thin McKibben actuator applying Deep Learning approaches to aid automatic therapy to the paralyzed patients and help them carry out the hand movement-based exercises. Convolutional Neural Network (CNN) algorithm will be used to support the training of the AI-enabled automated device. The proposed methodology will support stroke survivors to perform exercises independently to enhance their hand motor recovery. For this purpose, it involves pneumatic soft actuator technology using thin McKibben artificial muscles to create a cognitive potential to induce rehabilitation. A soft actuator is proposed so as to confirm the safety purposes of stroke patients.

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Section: Literature Reviewmentioning

confidence: 99%

Development of soft actuators for stroke rehabilitation using deep learning

Alshammari¹

2021

Int. j. adv. appl. sci.

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“…We developed thin soft McKibben muscles for mass production [22]. The muscles are light, small, and suitable for simple systems [23]. The Giacometti robot applies 4.0 mm McKibben actuators which will contract when being pressurized with air.…”

Section: A Actuator Characteristicsmentioning

confidence: 99%

Long-Legged Hexapod Giacometti Robot Using Thin Soft McKibben Actuator

Faudzi

Endo

Kurumaya

et al. 2018

IEEE Robot. Autom. Lett.

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This letter introduces a lightweight hexapod robot, Giacometti robot, made with long and narrow legs following the Alberto Giacometti's sculpture conception. The goal is achieved by, first, using multiple links with thin and soft McKibben actuators, and second, choosing a leg design which is narrow in comparison to its body's length and height, unlike conventional robot design. By such design characteristic, the leg will exhibit elastic deformations due to the low stiffness property of the thin link structure. Then, we model the leg structure and conduct the deflection analysis to confirm the capability of the leg to perform walking motion. The high force to weight ratio characteristics of the actuator provided the ability to drive the system, as shown by a static model and further validated experimentally. To compensate for the high elastic structural flexibility of the legs, two walking gaits namely customized Wave gait and Giacometti gait were introduced. The robot could walk successfully with both gaits at maximum speed of 0.005 and 0.05 m/s, respectively. It is envisaged that the lightweight Giacometti robot design can be very useful in legged robotic exploration.

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“…A sea urchininspired amphibious robot using actuated rigid spines and extensible soft legs was used to investigate bio-inspired locomotion patterns in aquatic and terrestrial conditions [16]. A quadruped robot comprising groups of interconnected thin and soft McKibben actuators demonstrated locomotion on wet and dry terrains, using a variety of walking and crawling gaits [17]. A worm-inspired soft robot, featuring serially connected and individually driven pneumatic actuators, was used to investigate crawling and swimming gaits [18].…”

Section: Introductionmentioning

confidence: 99%

Soft Fluidic Actuator for Locomotion in Multi-Phase Environments

Gkliva

Kruusmaa

2022

IEEE Robot. Autom. Lett.

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This letter presents the design, development, and experimental assessment of a soft fluidic actuator that can enable locomotion in a variety of aquatic and terrestrial environments. Most actuation strategies for amphibious locomotion rely on rigid, fast moving components to generate thrust and tractive forces. Our prototype, comprising soft materials, and relying on simple motion planning and control strategies, demonstrates two gaits, that we employ for locomotion in two vastly different scenarios, underwater swimming and moving on granular terrain with varying levels of water content. By adjusting its internal pressure, the actuator dynamically varies its stiffness and shape, and transitions between wheel and soft paddle form. Experimental results of locomotion in controlled laboratory conditions serve as proof-of-concept for the proposed actuator's efficacy. Using two different motion patterns and control schemes, we show that this prototype achieves both thrust and tractive forces.

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Soft-amphibious robot using thin and soft McKibben actuator

Cited by 32 publications

References 17 publications

Development of soft actuators for stroke rehabilitation using deep learning

Development of soft actuators for stroke rehabilitation using deep learning

Long-Legged Hexapod Giacometti Robot Using Thin Soft McKibben Actuator

Soft Fluidic Actuator for Locomotion in Multi-Phase Environments

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