JOURNAL ARTICLE

Octopus-inspired sensorized soft arm for environmental interaction.

  • Published In: Science Robotics, 2023, v. 8, n. 84. P. 1 1 of 3

  • Database: Applied Science & Technology Source Ultimate 2 of 3

  • Authored By: Xie, Zhexin; Yuan, Feiyang; Liu, Jiaqi; Tian, Lufeng; Chen, Bohan; Fu, Zhongqiang; Mao, Sizhe; Jin, Tongtong; Wang, Yun; He, Xia; Wang, Gang; Mo, Yanru; Ding, Xilun; Zhang, Yihui; Laschi, Cecilia; Wen, Li 3 of 3

Abstract

Octopuses can whip their soft arms with a characteristic "bend propagation" motion to capture prey with sensitive suckers. This relatively simple strategy provides models for robotic grasping, controllable with a small number of inputs, and a highly deformable arm with sensing capabilities. Here, we implemented an electronics-integrated soft octopus arm (E-SOAM) capable of reaching, sensing, grasping, and interacting in a large domain. On the basis of the biological bend propagation of octopuses, E-SOAM uses a bending-elongation propagation model to move, reach, and grasp in a simple but efficient way. E-SOAM's distal part plays the role of a gripper and can process bending, suction, and temperature sensory information under highly deformed working states by integrating a stretchable, liquid-metal–based electronic circuit that can withstand uniaxial stretching of 710% and biaxial stretching of 270% to autonomously perform tasks in a confined environment. By combining this sensorized distal part with a soft arm, the E-SOAM can perform a reaching-grasping-withdrawing motion across a range up to 1.5 times its original arm length, similar to the biological counterpart. Through a wearable finger glove that produces suction sensations, a human can use just one finger to remotely and interactively control the robot's in-plane and out-of-plane reaching and grasping both in air and underwater. E-SOAM's results not only contribute to our understanding of the function of the motion of an octopus arm but also provide design insights into creating stretchable electronics-integrated bioinspired autonomous systems that can interact with humans and their environments. [ABSTRACT FROM AUTHOR]

Additional Information

  • Source:Science Robotics. 2023/11, Vol. 8, Issue 84, p1
  • Document Type:Article
  • Subject Area:Engineering
  • Publication Date:2023
  • ISSN:24709476
  • DOI:10.1126/scirobotics.adh7852
  • Accession Number:176964801
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