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A piezoelectric micro-electro-mechanical system vector sensor with a mushroom-shaped proof mass for a dipole beam pattern

Title
A piezoelectric micro-electro-mechanical system vector sensor with a mushroom-shaped proof mass for a dipole beam pattern
Author(s)
Yeon, AraYeo, Hong GooRoh, YongraeKim, KyungseopSeo, Hee-SeonChoi, Hongsoo
Issued Date
2021-12
Citation
Sensors and Actuators A: Physical, v.332
Type
Article
Author Keywords
HydrophoneVector sensorMicro-electro-mechanical system (MEMS)PiezoelectricThin film
Keywords
Resonance frequenciesThin-filmsUnderwater communicationVector hydrophonesVector sensorsPiezoelectricityEtchingHydrophonesLead zirconate titanateMechanicsMEMSNatural frequenciesThin filmsTitanium compoundsVectorsZirconium compoundsBeam patternMEMS (microelectromechanical system)Micro-electro-mechanical systemProof massPiezoelectric
ISSN
0924-4247
Abstract
Vector hydrophones based on a micro-electro-mechanical system (MEMS) hold great promise for underwater communications, due to their potential for miniaturization and mass production. Piezoelectric materials have recently been utilized in the fabrication of MEMS-based vector hydrophones, as less power is typically required for their operation. Here, we propose a millimeter-scale piezoelectric MEMS vector sensor with a suspended cross-shaped beam and a mushroom-shaped proof mass configuration. This design was inspired by the bio-transducer of the lateral line of fish. Sensor fabrication involved piezoelectric Pb(Zr0.52Ti0.48)O3 thin-film deposition by radio-frequency magnetron sputtering onto the beam structure, followed by a multi-etching process and assembly using a three-axis microassembly technique. The fabricated MEMS vector sensor showed a resonance frequency above the working frequency range, which was suitable for naval applications. The directivity of the proposed sensor was determined by dipole patterns in the x and y directions, with a maximum relative sensitivity difference of −42 dB at 1 kHz. Finite element analysis results for the resonance frequency and directivity were in good agreement with the experimental results, suggesting that the proposed vector sensor could be used in underwater communications as a vector hydrophone. © 2021 Elsevier B.V.
URI
http://hdl.handle.net/20.500.11750/15615
DOI
10.1016/j.sna.2021.113129
Publisher
Elsevier
Related Researcher
  • 최홍수 Choi, Hongsoo
  • Research Interests Micro/Nano robot; Neural prostheses; MEMS; BMI; MEMS/NEMS; BioMEMS; MEMS 초음파 트랜스듀스; 인공와우
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Appears in Collections:
Department of Robotics and Mechatronics Engineering Bio-Micro Robotics Lab 1. Journal Articles

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