Rapid two-anchor crawling from a milliscale prismatic-push–pull (3P) robot

Zhou, Wei; Gravish, Nick

doi:10.1088/1748-3190/aba8ab

Cited by 5 publications

(2 citation statements)

References 75 publications

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“…The three-linked-sphere robot uses a simple, one-degree-of-freedom actuation that can be miniaturized to a subcentimeter scale. For example, in contrast to COTS, the size of the actuator can be significantly reduced using piezoelectric and shape memory alloy [44][45][46] and recently developed 3D-printed actuators, which use shape memory polymers, hygroscopic and thermal-responsive composite hydrogels, liquid crystal elastomers, and magnetic composite materials to produce soft robots with tailored deformation. [47,48] The integration with recent work in advanced manufacturing for electronics, such as with 3D printing, [49][50][51][52][53][54] or conformal electronics [43,55] can be used to reduce the footprint of the electronics packaging (e.g., by distributing the components with freeform, 3D interconnects, [56][57][58] printed active electronics, [41,59] and printed batteries [60][61][62] ).…”

Section: Discussionmentioning

confidence: 99%

A 3D‐Printed Self‐Learning Three‐Linked‐Sphere Robot for Autonomous Confined‐Space Navigation

Elder

Zou

Ghosh

et al. 2021

Advanced Intelligent Systems

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Reinforcement learning control methods can impart robots with the ability to discover effective behavior, reducing their modeling and sensing requirements, and enabling their ability to adapt to environmental changes. However, it remains challenging for a robot to achieve navigation in confined and dynamic environments, which are characteristic of a broad range of biomedical applications, such as endoscopy with ingestible electronics. Herein, a compact, 3D‐printed three‐linked‐sphere robot synergistically integrated with a reinforcement learning algorithm that can perform adaptable, autonomous crawling in a confined channel is demonstrated. The scalable robot consists of three equally sized spheres that are linearly coupled, in which the extension and contraction in specific sequences dictate its navigation. The ability to achieve bidirectional locomotion across frictional surfaces in open and confined spaces without prior knowledge of the environment is also demonstrated. The synergistic integration of a highly scalable robotic apparatus and the model‐free reinforcement learning control strategy can enable autonomous navigation in a broad range of dynamic and confined environments. This capability can enable sensing, imaging, and surgical processes in previously inaccessible confined environments in the human body.

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Section: Discussionmentioning

confidence: 99%

A 3D‐Printed Self‐Learning Three‐Linked‐Sphere Robot for Autonomous Confined‐Space Navigation

Elder

Zou

Ghosh

et al. 2021

Advanced Intelligent Systems

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“…It can crawl upstairs in an ‘S’ shape mode and pass through low gaps in an omega-shaped locomotion mode. Zhou et al [ 13 ] designed a millimeter-scale ground crawling robot driven by a novel prismatic mechanism capable of operating in a wide range of actuation frequencies, achieving a maximum ground crawling velocity of ~24 body-length(BL)/s. Muralidharan et al [ 14 ] developed a biomimetic soft worm robot driven by SMA which utilized the bending behavior of the robot to achieve steering in peristaltic and two-anchor locomotion.…”

Section: Introductionmentioning

confidence: 99%

A Dielectric Elastomer Actuator-Driven Vibro-Impact Crawling Robot

Yan

Cai

et al. 2022

Micromachines

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Over the last decade, many bio-inspired crawling robots have been proposed by adopting the principle of two-anchor crawling or anisotropic friction-based vibrational crawling. However, these robots are complicated in structure and vulnerable to contamination, which seriously limits their practical application. Therefore, a novel vibro-impact crawling robot driven by a dielectric elastomer actuator (DEA) is proposed in this paper, which attempts to address the limitations of the existing crawling robots. The novelty of the proposed vibro-impact robot lies in the elimination of anchoring mechanisms or tilted bristles in conventional crawling robots, hence reducing the complexity of manufacturing and improving adaptability. A comprehensive experimental approach was adopted to characterize the performance of the robot. First, the dynamic response of the DEA-impact constraint system was characterized in experiments. Second, the performance of the robot was extensively studied and the fundamental mechanisms of the vibro-impact crawling locomotion were analyzed. In addition, effects of several key parameters on the robot's velocity were investigated. It is demonstrated that our robot can realize bidirectional motion (both forward and backward) by simple tuning of the key control parameters. The robot demonstrates a maximum forward velocity of 21.4 mm/s (equivalent to 0.71 body-length/s), a backward velocity of 16.9 mm/s, and a load carrying capacity of 9.5 g (equivalent to its own weight). The outcomes of this paper can offer guidelines for high-performance crawling robot designs, and have potential applications in industrial pipeline inspections, capsule endoscopes, and disaster rescues.

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