Defected twisted ring topology for autonomous periodic flip–spin–orbit soft robot

Qi, Fangjie; Li, Yanbin; Hong, Yaoye; Zhao, Yao; Qing, Haitao; Yin, Jie

doi:10.1073/pnas.2312680121

Cited by 11 publications

(2 citation statements)

References 34 publications

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“…This study is an elegant example of an environmentally adaptive response and a specific task, highlighting the potential of actuator systems for autonomous operations. The embodied physical intelligence of soft actuators has been designed for self-adaptive movements in various unstructured environments 12 , 13 , 44 , 92 , 93 . As shown in Fig.…”

Section: Introductionmentioning

confidence: 99%

Self-sustainable autonomous soft actuators

Nie,

Wang,

Yang

2024

Commun Chem

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Self-sustainable autonomous locomotion is a non-equilibrium phenomenon and an advanced intelligence of soft-bodied organisms that exhibit the abilities of perception, feedback, decision-making, and self-sustainment. However, artificial self-sustaining architectures are often derived from algorithms and onboard modules of soft robots, resulting in complex fabrication, limited mobility, and low sensitivity. Self-sustainable autonomous soft actuators have emerged as naturally evolving systems that do not require human intervention. With shape-morphing materials integrating in their structural design, soft actuators can direct autonomous responses to complex environmental changes and achieve robust self-sustaining motions under sustained stimulation. This perspective article discusses the recent advances in self-sustainable autonomous soft actuators. Specifically, shape-morphing materials, motion characteristics, built-in negative feedback loops, and constant stimulus response patterns used in autonomous systems are summarized. Artificial self-sustaining autonomous concepts, modes, and deformation-induced functional applications of soft actuators are described. The current challenges and future opportunities for self-sustainable actuation systems are also discussed.

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Section: Introductionmentioning

confidence: 99%

Self-sustainable autonomous soft actuators

Nie,

Wang,

Yang

2024

Commun Chem

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“…These advantages include the integrated sensors and actuators for enabling intelligent functionality, noiseless deformation, and mechanical tunability [3]. Active machines that respond to electrical, magnetic, and optical stimuli also provide benefits such as wireless remote control and manipulation through obstacles [4]. As a result, active machines show immense potential in various fields, including soft robotics, medical devices, and micronano devices [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Mathematical Modeling of the Displacement of a Light-Fuel Self-Moving Automobile with an On-Board Liquid Crystal Elastomer Propulsion Device

Qiu,

Chen,

Dai

et al. 2024

Mathematics

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The achievement and control of desired motions in active machines often involves precise manipulation of artificial muscles in a distributed and sequential manner, which poses significant challenges. A novel motion control strategy based on self-oscillation in active machines offers distinctive benefits, such as direct energy harvesting from the ambient environment and the elimination of complex controllers. Drawing inspiration from automobiles, a self-moving automobile designed for operation under steady illumination is developed, comprising two wheels and a liquid crystal elastomer fiber. To explore the dynamic behavior of this self-moving automobile under steady illumination, a nonlinear theoretical model is proposed, integrating with the established dynamic liquid crystal elastomer model. Numerical simulations are conducted using the Runge-Kutta method based on MATLAB software, and it is observed that the automobile undergoes a supercritical Hopf bifurcation, transitioning from a static state to a self-moving state. The sustained periodic self-moving is facilitated by the interplay between light energy and damping dissipation. Furthermore, the conditions under which the Hopf bifurcation occurs are analyzed in detail. It is worth noting that increasing the light intensity or decreasing rolling resistance coefficient can improve the self-moving average velocity. The innovative design of the self-moving automobile offers advantages such as not requiring an independent power source, possessing a simple structure, and being sustainable. These characteristics make it highly promising for a range of applications including actuators, soft robotics, energy harvesting, and more.

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Embedded Physical Intelligence in Liquid Crystalline Polymer Actuators and Robots

Feng,

He,

Zhang

2024

Advanced Materials

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Responsive materials possess the inherent capacity to autonomously sense and respond to various external stimuli, demonstrating physical intelligence. Among the diverse array of responsive materials, liquid crystalline polymers (LCPs) stand out for their remarkable reversible stimuli‐responsive shape‐morphing properties and their potential for creating soft robots. While numerous reviews have extensively detailed the progress in developing LCP‐based actuators and robots, there exists a need for comprehensive summaries that elucidate the underlying principles governing actuation and how physical intelligence is embedded within these systems. This review provides a comprehensive overview of recent advancements in developing actuators and robots endowed with physical intelligence using LCPs. Our review is structured around the stimulus conditions and categorizes the studies involving responsive LCPs based on the fundamental control and stimulation logic and approach. Specifically, we examine three main categories: systems that respond to changing stimuli, those operating under constant stimuli, and those equipped with learning and logic control capabilities. Furthermore, we outline the persisting challenges that need to be addressed and discuss the future avenues of research in this dynamic field.This article is protected by copyright. All rights reserved

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Defected twisted ring topology for autonomous periodic flip–spin–orbit soft robot

Cited by 11 publications

References 34 publications

Self-sustainable autonomous soft actuators

Self-sustainable autonomous soft actuators

Mathematical Modeling of the Displacement of a Light-Fuel Self-Moving Automobile with an On-Board Liquid Crystal Elastomer Propulsion Device

Embedded Physical Intelligence in Liquid Crystalline Polymer Actuators and Robots

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