Insect-scale jumping robots enabled by a dynamic buckling cascade

Wang, Yuzhe; Wang, Qiong; Liu, Mingchao; Qin, Yimeng; Cheng, Liuyang; Bolmin, Ophelia; Alleyne, Marianne; Wissa, Aimy; Baughman, Ray H.; Vella, Dominic; Tawfick, Sameh

doi:10.1073/pnas.2210651120

Cited by 27 publications

(18 citation statements)

References 49 publications

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“…Another design framework is based on the evolutionary design approach, which combines elements more akin to natural evolution or evolutionary algorithms. 25 Starting from a general concept of design option, several different configurations, that can be referred to as "phenotypes," are evolving through their own evolution pathways by adding the minimum number of details in each iteration and ensuring their cross-interactions to achieve the targets iteratively and incrementally through design-test cycles. In retrospect, this iterative design approach is reminiscent of evolution by natural selection, where the complexity of the functions and the vastness of the design space preclude existing mathematical frameworks.…”

Section: Key Pointsmentioning

confidence: 99%

“…This framework holds the potential for significant advancements in the optimization of soft robotic systems. Another design framework is based on the evolutionary design approach, which combines elements more akin to natural evolution or evolutionary algorithms 25 . Starting from a general concept of design option, several different configurations, that can be referred to as “phenotypes,” are evolving through their own evolution pathways by adding the minimum number of details in each iteration and ensuring their cross‐interactions to achieve the targets iteratively and incrementally through design‐test cycles.…”

Section: Soft Actuatorsmentioning

confidence: 99%

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Pioneering healthcare with soft robotic devices: A review

Wang,

Xie,

Huang

et al. 2024

Smart Medicine

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Recent advancements in soft robotics have been emerging as an exciting paradigm in engineering due to their inherent compliance, safe human interaction, and ease of adaptation with wearable electronics. Soft robotic devices have the potential to provide innovative solutions and expand the horizons of possibilities for biomedical applications by bringing robots closer to natural creatures. In this review, we survey several promising soft robot technologies, including flexible fluidic actuators, shape memory alloys, cable‐driven mechanisms, magnetically driven mechanisms, and soft sensors. Selected applications of soft robotic devices as medical devices are discussed, such as surgical intervention, soft implants, rehabilitation and assistive devices, soft robotic exosuits, and prosthetics. We focus on how soft robotics can improve the effectiveness, safety and patient experience for each use case, and highlight current research and clinical challenges, such as biocompatibility, long‐term stability, and durability. Finally, we discuss potential directions and approaches to address these challenges for soft robotic devices to move toward real clinical translations in the future.

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Section: Key Pointsmentioning

confidence: 99%

Section: Soft Actuatorsmentioning

confidence: 99%

Pioneering healthcare with soft robotic devices: A review

Wang,

Xie,

Huang

et al. 2024

Smart Medicine

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“…For instance, beetles utilize their bodies to store energy, [19] which, once accumulated to a critical level, triggers a snapping transformation, facilitating the rapid release of stored energy and enabling high jumps (Figure 1a). Inspired by such natural phenomena, Wang [7] et al developed an insect-scale jumping robot that rivals or surpasses natural creatures and existing robotic counterparts. The snapping mechanism obviates the need for high response speeds in the actuators.…”

Section: Doi: 101002/advs202307088mentioning

confidence: 99%

“…Inspired by nature, soft-bodied robots exhibit high compliance, enabling them to adapt effectively to diverse environments. Recent advancements in materials and actuation mechanisms have facilitated the emulation of various movements displayed by natural organisms, including flying, [1,2] crawling, [3][4][5] jumping, [6][7][8][9] and swimming. [10,11] Among these locomotor modes, jumping has garnered considerable interest as an efficient means of traversing unstructured environments, particularly for small insects seeking survival space.…”

Section: Introductionmentioning

confidence: 99%

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Snapping for 4D‐Printed Insect‐Scale Metal‐Jumper

Yang,

Wang

2023

Advanced Science

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The replication of jumping motions observed in small organisms poses a significant challenge due to size‐related effects. Shape memory alloys (SMAs) exhibit a superior work‐to‐weight ratio, making them suitable for jumping actuators. However, the SMAs advantages are hindered by the limitations imposed by their single actuator configuration and slow response speed. This study proposes a novel design approach for an insect‐scale shape memory alloy jumper (net‐shell) using 4D printing technology and the bistable power amplification mechanism. The energy variations of the SMA net‐shell under different states and loads are qualitatively elucidated through a spring‐mass model. To optimize the performance of the SMA net‐shell, a non‐contact photo‐driven technique is employed to induce its shape transition. Experimental investigations explore the deformation response, energy release of the net‐shell, and the relationship between the light power density. The results demonstrate that the SMA net‐shell exhibits remarkable jumping capabilities, achieving a jump height of 60 body lengths and takeoff speeds of up to 300 body lengths per second. Furthermore, two illustrative cases highlight the potential of net‐shells for applications in unstructured terrains. This research contributes to miniaturized jumping mechanisms by providing a new design approach integrating smart materials and advanced structures.

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Soft Pumps: Catalysts for Advancing Fluid‐Driven Soft Robots

Wang,

Liang

2024

Adv Eng Mater

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Fluid‐driven soft robotics, inspired by biological systems, has emerged as a dynamic field in the past decades. Soft pumps, crucial components for soft robots to be untethered or wearable on the human body, offer unique features for propelling fluids. This article provides a concise perspective on recent advancements in soft pumps, including combustion‐driven, electrohydrodynamic, dielectric elastomer actuation, dielectrophoretic liquid zipping, magnetic actuation, thermally active soft pumps, and fluid‐driven volume amplification. Each technology is examined in terms of its working principles, advantages, and challenges. Looking ahead, critical challenges must be addressed to facilitate successful integration of soft pumps into real‐world applications, including healthcare and wearable‐assistive devices. As soft robotics continues to advance, future research directions involve enhancing safety measures, optimizing material properties, improving control precision, and advancing flexible electronics to ensure the seamless adoption of soft pumps in diverse real‐world scenarios. This perspective article serves as a guide to the current trends and challenges in the evolving field of soft pumps, laying the foundation for the future development and application of fluid‐driven soft robotics.

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Insect-scale jumping robots enabled by a dynamic buckling cascade

Cited by 27 publications

References 49 publications

Pioneering healthcare with soft robotic devices: A review

Pioneering healthcare with soft robotic devices: A review

Snapping for 4D‐Printed Insect‐Scale Metal‐Jumper

Soft Pumps: Catalysts for Advancing Fluid‐Driven Soft Robots

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