A Cavity-Type Pressure Sensor Array With High Anti-Disturbance Performance Inspired by Fish Lateral Line Canal

Effective sensing is challenging in real underwater environment swarming with various disturbances. However, most research on underwater sensors has been conducted in still water, which may not provide sufficient insights for environments with disturbances. In addressing this issue, our article not...

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Bibliographic Details
Published inIEEE sensors journal Vol. 24; no. 9; pp. 14050 - 14058
Main Authors Yang, Qian, Hu, Qiao, Shan, Liuhao, Jiang, Guangyu, Yao, Yuanji, Tang, Long, Zhu, Zicai, Aabloo, Alvo
Format Journal Article
LanguageEnglish
Published New York IEEE 01.05.2024
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Anti-disturbance
Dipoles
Disturbances
Fish
ionic polymer-mental composite (IPMC)
Irrigation
lateral line canal
Latex
Localization
Location awareness
Oils
Pressure sensors
Robot sensing systems
Self oscillation
sensor
Sensor arrays
Sensors
Signal detection
Swarming
Target detection
Three dimensional printing
Underwater detectors
underwater localization
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Summary:Effective sensing is challenging in real underwater environment swarming with various disturbances. However, most research on underwater sensors has been conducted in still water, which may not provide sufficient insights for environments with disturbances. In addressing this issue, our article not only proposes the development of anti-disturbance sensor units but also delves into evaluating the localization capabilities of artificial lateral line arrays in disturbed water environments. Concretely, inspired by the lateral line canal system of fish, we proposed a cavity-type pressure sensing device (denoted as a C-sensor) with notable anti-disturbance performance. On the one hand, a 3D-printed resin cavity is filled with silicone oil, with flexible latex film packaging the upper and lower openings to achieve anti-disturbance capabilities akin to those of fish lateral line canals. On the other hand, employing ionic polymer-mental composite (IPMC) materials based on ion sensing principles, the sensor generates electrical signals similar to sensing cilia in fish lateral line systems. The results demonstrated that the cavityless sensor (denoted as N-sensor) showed self-oscillation behavior, leading to significant errors in weak target signal detection and even sensor failure in extreme cases. However, the C-sensor exhibits remarkable sensing performance in still water and water disturbances, thereby confirming the effectiveness of its cavity-type structure in mitigating the impact of water disturbances. Furthermore, we developed two distinct artificial lateral line arrays based on the above sensors (C-array and N-array). The experimental results showed a marked 78% reduction in mean localization error for C-array compared to N-array. Additionally, the C-array exhibited good ability in multiple dipoles detection. Such results indicate the superior applicability of the C-array within real complex underwater environments, promoting the practical application of IPMC sensors.
ISSN:1530-437X
1558-1748
DOI:10.1109/JSEN.2024.3381162