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Highly sensitive and broadband meta-mechanoreceptor via mechanical frequency-division multiplexing

Chong Li, Xinxin Liao, Zhi-Ke Peng, Guang Meng and Qingbo He ()
Additional contact information
Chong Li: Shanghai Jiao Tong University
Xinxin Liao: Shanghai Jiao Tong University
Zhi-Ke Peng: Shanghai Jiao Tong University
Guang Meng: Shanghai Jiao Tong University
Qingbo He: Shanghai Jiao Tong University

Nature Communications, 2023, vol. 14, issue 1, 1-11

Abstract: Abstract Bio-mechanoreceptors capable of micro-motion sensing have inspired mechanics-guided designs of micro-motion sensors in various fields. However, it remains a major challenge for mechanics-guided designs to simultaneously achieve high sensitivity and broadband sensing due to the nature of resonance effect. By mimicking rat vibrissae, here we report a metamaterial mechanoreceptor (MMR) comprised of piezoelectric resonators with distributed zero effective masses featuring a broad range of local resonances, leading to near-infinite sensitivity for micro-motion sensing within a broad bandwidth. We developed a mechanical frequency-division multiplexing mechanism for MMR, in which the measured micro-motion signal is mechanically modulated in non-overlapping frequency bands and reconstructed by a computational multi-channel demodulation approach. The maximum sensitivity of MMR is improved by two orders of magnitude compared to conventional mechanics-guided mechanoreceptors, and its bandwidth with high sensitivity is extendable towards both low-frequency and high-frequency ranges in 0–12 kHz through tuning the local resonance of each individual sensing cell. The MMR is a promising candidate for highly sensitive and broadband micro-motion sensing that was previously inaccessible for mechanics-guided mechanoreceptors, opening pathways towards spatio-temporal sensing, remote-vibration monitoring and smart-driving assistance.

Date: 2023
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DOI: 10.1038/s41467-023-41222-9

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