An Improved Lumped Element Model for Circular-Shape pMUTs

Sedat Pala;Liwei Lin
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引用次数: 4

Abstract

This paper presents an improved lumped element model for clamped, circular-shape, piezoelectric micromachined ultrasonic transducers (pMUTs). A small signal equivalent circuit is developed to include electrical, mechanical, and acoustic domains, which are analyzed separately and combined with the associated couplings. For the first time, a two-term mode shape approach is adapted to reveal intrinsic and extrinsic properties of a pMUT, such as equivalent circuit parameters, input impedance, velocity, displacement, bandwidth, quality factor, directivity, and the on-axis pressure in the near and far field. These properties are compared with prior reports in the literature and exact solutions, as well as Finite Element Method (FEM) simulations. The errors relative to exact solution for all these properties are below 0.5%. These improvements in error are from 5x to about 3 orders of magnitude better than those of prior works. As such, the improved model could be helpful in design and simulation tools for pMUTs.
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一种改进的圆形pMUTs集总元模型
本文提出了一种改进的圆形夹紧型压电微机械超声换能器的集总元模型。开发了一个小信号等效电路,包括电气,机械和声学域,它们分别进行分析,并与相关的耦合组合在一起。首次采用两项模态振型方法来揭示pMUT的内在和外在特性,如等效电路参数、输入阻抗、速度、位移、带宽、质量因子、指向性以及近场和远场的轴上压力。这些性质与先前的文献报告和精确解以及有限元法(FEM)模拟进行了比较。相对于所有这些属性的精确解的误差都在0.5%以下。这些误差的改善从5倍到大约3个数量级比以前的工作。因此,改进的模型可以为pmut的设计和仿真工具提供帮助。
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