Biomimetic Hydrodynamic Sensor with Whisker Array Architecture and Multidirectional Perception Ability

Biomimetic Hydrodynamic Sensor with Whisker Array Architecture and Multidirectional Perception Ability

Abstract The rapid development of ocean exploration and underwater robot technology has put forward new requirements for underwater sensing methods, which can be used for hydrodynamic characteristics perception, underwater target tracking, and even underwater cluster communication. Here, inspired by...

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Bibliographic Details
Main Authors: Huangzhe Dai, Chengqian Zhang, Hao Hu, Zhezai Hu, Haonan Sun, Kan Liu, Tiefeng Li, Jianzhong Fu, Peng Zhao, Huayong Yang
Format: Article
Language:English
Published: Wiley 2024-10-01
Series:Advanced Science
Subjects:
Biomimetic sensors
hydrodynamic perception
magnetic soft sensors
underwater electronics
whisker array
Online Access:https://doi.org/10.1002/advs.202405276
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Summary:Abstract The rapid development of ocean exploration and underwater robot technology has put forward new requirements for underwater sensing methods, which can be used for hydrodynamic characteristics perception, underwater target tracking, and even underwater cluster communication. Here, inspired by the specialized undulated surface structure of the seal whisker and its ability to suppress vortex‐induced vibration, a multidirectional hydrodynamic sensor based on biomimetic whisker array structure and magnetic 3D self‐decoupling theory is introduced. The magnetic‐based sensing method enables wireless connectivity between the magnetic functional structures and electronics, simplifying device design and endowing complete watertightness. The 3D self‐decoupling capability enables the sensor, like a seal or other organisms, to perceive arbitrary whisker motions caused by the action of water flow without complex calibration and additional sensing units. The whisker sensor is capable of detecting a variety of hydrodynamic information, including the velocity (RMSE < 0.061 m s−1) and direction of the steady flow field, the frequency (error < 0.05 Hz) of the dynamic vortex wake, and the orientation (error < 7°) of the vortex wake source, demonstrating its extensive potential for underwater environmental perception and communication, especially in deep sea conditions.
ISSN:2198-3844

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