A Review of Somatic Design for Soft Robotic Grippers: From Parts Integration to Functional Synergy

A Review of Somatic Design for Soft Robotic Grippers: From Parts Integration to Functional Synergy

Somatic design is crucial for soft grippers to emulate the embodied intelligence of their biological counterparts, due to the blurry boundaries among material, structure, and function. There are five critical parts in somatic design, including morphology, material, fabrication, actuation, and variab...

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Bibliographic Details
Published in:Advanced intelligent systems Vol. 6; no. 8
Main Authors: Xu, Zhidong, Shi, Peipei, Yan, Jihong, Zhao, Jie
Format: Journal Article
Language:English
Published: Weinheim John Wiley & Sons, Inc 01-08-2024
Wiley
Subjects:
Actuation
Adaptability
Compliance
Control algorithms
Coupling
coupling enhancement
Critical components
embodied intelligence
functional synergy
Grippers
Intelligence
Morphology
Robotics
soft robotic grippers
somatic design
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Summary:Somatic design is crucial for soft grippers to emulate the embodied intelligence of their biological counterparts, due to the blurry boundaries among material, structure, and function. There are five critical parts in somatic design, including morphology, material, fabrication, actuation, and variable stiffness. The strong nonlinear coupling among these factors often leads to mutual influence and functional compromise after integration. Herein, methods and strategies harnessed in these parts for performance improvement of soft grippers are systematically reviewed, particularly clarifying how to exert the coupling enhancement effects of the somatic parts for functional synergy. Finally, the remaining challenges and the future development directions of soft grippers for organism‐like intelligence and wide‐range applications are discussed. Somatic design is crucial for soft grippers to emulate the embodied intelligence of their biological counterparts, due to the blurry boundaries among material, structure and function. There are five critical parts in somatic design, including morphology, material, fabrication, actuation, and variable stiffness. The strong nonlinear coupling among these factors often leads to mutual influence and functional compromise after integration. Existing excellent reviews about soft grippers tend to focus more on summarizing and discussing the partial factors of somatic design, and ignore the importance of somatic‐part collaborative design. In this review, a systematic somatic design guide that covers all five parts while investigating their functional synergy is provided. The remaining challenges and the future development directions of soft grippers for organism‐like intelligence and wide‐range applications are discussed.
ISSN:2640-4567
2640-4567
DOI:10.1002/aisy.202300788