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28 April 2023 Piezoelectric metamaterial with self-tuning resonant shunt circuits
Yupei Jian, Yincheng Shen, Lihua Tang, Guobiao Hu, Kean Aw
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Proceedings Volume 12483, Active and Passive Smart Structures and Integrated Systems XVII; 124831F (2023) https://doi.org/10.1117/12.2657612
Event: SPIE Smart Structures + Nondestructive Evaluation, 2023, Long Beach, California, United States
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Abstract
The bandgap generated in piezoelectric metamaterials with resonant shunt circuits unveils a great potential for vibration control. This paper presents a piezoelectric metamaterial with the capability of broadband vibration attenuation by adaptive bandgap tuning. Unlike the widely used synthetic impedance circuit, a self-tuning resonant shunt circuit by integrating a microcontroller-driven digital potentiometer into the synthetic inductor circuit is developed to achieve the bandgap adjustment of the piezoelectric metamaterial. Specifically, the excitation frequency is detected by the microcontroller, and the synthetic inductance in the resonant shunt circuit is adjusted in real-time based on a given criterion. An experimental study is conducted to demonstrate the dynamic behavior and vibration suppression performance of the developed piezoelectric metamaterial. The results confirm that the self-tuning resonant shunt circuit can rapidly respond to frequency-varying vibration sources and endow the piezoelectric metamaterial with an extremely wide vibration attenuation region.
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Yupei Jian, Yincheng Shen, Lihua Tang, Guobiao Hu, and Kean Aw "Piezoelectric metamaterial with self-tuning resonant shunt circuits", Proc. SPIE 12483, Active and Passive Smart Structures and Integrated Systems XVII, 124831F (28 April 2023); https://doi.org/10.1117/12.2657612
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KEYWORDS
Vibration
Metamaterials
Signal attenuation
Ferroelectric materials
Microcontrollers
Resistance
Process control
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