Trimmed helicoids: an architectured soft structure yielding soft robots with high precision, large workspace, and compliant interactions

Guan, Qinghua; Stella, Francesco; Della Santina, Cosimo; Leng, Jinsong; Hughes, Josie

doi:10.1038/s44182-023-00004-7

Cited by 10 publications

(2 citation statements)

References 47 publications

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“…Although trunk-like soft arms are in principle highly dexterous and adaptable, their performance in terms of payload and spatial movements is limited and requires a very careful design, balancing the influence of key design parameters [41]. This also includes the development and use of architectured structures that indeed are changing the means by which soft robots are designed and fabricated, exploiting material properties, in terms of topology and geometry, that allow to control physical and mechanical structural properties [42]. In any case, the hyper-redundancy of soft robots implies a sensitivity to the modification of the material properties of the structure, the actuators and the sensors and this is a critical process of adaptation that can be solved, for example, by means of continual learning techniques [43].…”

Section: Discussionmentioning

confidence: 99%

Neural Simulation of Actions for Serpentine Robots

Morasso

2024

Preprint

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Neural or mental simulation of actions is a powerful tool for allowing cognitive agents to develop Prospection Capabilities that are crucial for learning and memorizing key aspects for challenging skills. In previous studies we developed an approach based on the animation of the redundant human Body Schema based on the Passive Motion Paradigm (PMP). In this paper we show that this approach can be easily extended to hyper-redundant serpentine robots as well as to hybrid configurations where the serpentine robot is functionally integrated with a traditional skeletal infrastructure. A simulation model is analyzed in detail showing that it incorporates spatio-temporal features discovered in the biomechanical studies of biological hydrostats like the elephant trunk or the octopus tentacles. It is proposed that such generative internal model can be the basis for a cognitive architecture appropriate for serpentine robots, independent of the underlying design and control technologies. Although robotic hydrostats have received a lot of attention in the last decades, the great majority of research activities have been focused on the actuation/sensorial/material technologies that can support the design of hyperredundant soft robots as well as the related control methodologies. The cognitive level of analysis has been limited to motion planning, without addressing synergy formation and metal time travel. This is where the contribution of the paper is focused on.

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Section: Discussionmentioning

confidence: 99%

Neural Simulation of Actions for Serpentine Robots

Morasso

2024

Preprint

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“…A continuum robot is a highly flexible and adaptable robotic system, capable of achieving complex motions even in the most constrained environments. The use of silicone rubber, fabrics or soft TPU materials [1][2] [3] has made the soft continuum robot even more adaptive to its surroundings, enabling it to perform even more complex motions. Recently, there has been a surge of interest in continuum robots due to its variable curvature capability, making it an incredibly versatile and powerful tool for a wide range of applications [4][5] [6].…”

Section: Introductionmentioning

confidence: 99%

Dynamics Modeling and Verification of Parallel Extensible Soft Robot Based on Cosserat Rod Theory

Wang

et al. 2022

2022 IEEE 18th International Conference on Automation Science and Engineering (CASE)

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This paper introduces a Cosserat rod based mathematical model for modeling a self-controllable variable curvature soft continuum robot. This soft continuum robot has a hollow inner channel and was developed with the ability to perform variable curvature utilizing a growing spine. The growing spine is able to grow and retract while modifies its stiffness through milli-size particle (glass bubble) granular jamming. This soft continuum robot can then perform continuous curvature variation, unlike previous approaches whose curvature variation is discrete and depends on the number of locking mechanisms or manual configurations. The robot poses an emergent modeling problem due to the variable stiffness growing spine which is addressed in this paper. We investigate the property of growing spine stiffness and incorporate it into the Cosserat rod model by implementing a combined stiffness approach. We conduct experiments with the soft continuum robot in various configurations and compared the results with our developed mathematical model. The results show that the mathematical model based on the adapted Cosserat rod matches the experimental results with only a 3.3% error with respect to the length of the soft continuum robot.

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A Flexible, Architected Soft Robotic Actuator for Motorized Extensional Motion

Kim,

Kaarthik,

Truby

2024

Advanced Intelligent Systems

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To advance the design space of electrically‐driven soft actuators, a flexible, architected soft robotic actuator is presented for motor‐driven extensional motion. The actuator comprises a 3D printed, cylindrical handed shearing auxetic (HSA) structure and a deformable, internal rubber bellows shaft. The actuator linearly extends upon applying torque from a servo motor; the rubber bellows shaft is stretchable but resistant to torsional deflection, allowing it to transmit torque from the servo motor to the other end of the HSA. The high flexibility of the HSA and rubber bellows shaft enable the actuator to adaptively extend even when bent. The actuator's two components and its performance are mechanically characterized. Actuation strains of 45% elongation and a maximum blocked pushing force of about 8 N are demonstrated. The actuator's capabilities are showcased in two separate demonstrations: a crawling robot and a sensorized artificial muscle that integrates a microfluidic, liquid metal strain sensor. The architected material design approach for a robust, motor‐driven soft actuator provides several unique features—including a compact form factor and ease of use—over other motorized soft robotic actuators based on HSA assemblies or cable tendon mechanisms.

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Trimmed helicoids: an architectured soft structure yielding soft robots with high precision, large workspace, and compliant interactions

Cited by 10 publications

References 47 publications

Neural Simulation of Actions for Serpentine Robots

Neural Simulation of Actions for Serpentine Robots

Dynamics Modeling and Verification of Parallel Extensible Soft Robot Based on Cosserat Rod Theory

A Flexible, Architected Soft Robotic Actuator for Motorized Extensional Motion

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