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2-D 数组设计与制造,在 4 MHz 到 10 MHz 的频率下采用相移插层

2-D Array Design and Fabrication With Pitch-Shifting Interposer at Frequencies From 4 MHz up to 10 MHz.

出版信息

IEEE Trans Ultrason Ferroelectr Freq Control. 2022 Dec;69(12):3382-3391. doi: 10.1109/TUFFC.2022.3216602. Epub 2022 Nov 24.

DOI:10.1109/TUFFC.2022.3216602
PMID:36315528
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10353697/
Abstract

High element density and strict constraints of the element's size have significantly limited the design and fabrication of 2-D ultrasonic arrays, especially fully sampled 2-D arrays. Recently, 3-D printing technology has been one of the most rapidly developing fields. Along with the great progress of 3-D printing technology, complex and detailed 3-D structures have become readily available with a short iteration cycle, which allows us to reduce the complexity of routing and helps to ameliorate assembly problems in 2-D ultrasound array fabrication. In this work, we designed and fabricated 2-D ultrasound arrays for an array of applications with a pitch-shifting interposer, which allowed us to fit different array designs with the same circuit design and significantly reduce the requirements in routing and connection for 2-D array fabrication at frequencies from 4 to 10 MHz. Results demonstrated that this design would make 2-D arrays more available and affordable.

摘要

高元素密度和元素尺寸的严格限制极大地限制了二维超声阵列的设计和制造,特别是完全采样的二维阵列。最近,3D 打印技术是发展最快的领域之一。随着 3D 打印技术的巨大进步,复杂和详细的 3D 结构变得容易获得,并且迭代周期短,这使我们能够降低布线的复杂性,并有助于改善二维超声阵列制造中的装配问题。在这项工作中,我们设计并制造了具有相移插塞的二维超声阵列,用于一系列应用,这使得我们可以使用相同的电路设计来适应不同的阵列设计,并显著降低从 4 到 10MHz 的频率的二维阵列制造中对布线和连接的要求。结果表明,这种设计将使二维阵列更易于使用和负担得起。

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