三维体积超声成像与32×32 CMUT阵列集成前端集成电路使用倒装芯片键合技术

A. Bhuyan, J. Choe, Byung-chul Lee, I. Wygant, A. Nikoozadeh, Ömer Oralkan, B. Khuri-Yakub
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引用次数: 44

摘要

三维超声成像在医学领域日益普及。与传统的2D成像系统相比,3D成像可以提供组织结构的详细视图,使医生更容易诊断。此外,二维图像切片可以在换能器的不同方向形成,使检查较少依赖于超声医师的技能。然而,在开发3D成像系统中存在各种挑战,例如大量元素的集成,以及从大量通道接收的数据集的后处理。2D传感器阵列通常与探头手柄中的定制ic集成在一起,以执行一些中间波束形成,并减少与成像系统的电缆连接数量。电容式微机械超声换能器(CMUTs)已成为压电换能器的替代品。作为MEMS器件,它们极大地受益于灵活性和易于制造,并且可以与电子设备无缝集成。先前的工作演示了cmut和虚拟ic与中间中间层的3D堆叠。然而,这更多地代表了3D集成的机械演示。在本文中,我们提出了一个全功能的3D超声成像系统,包括32×32 2D CMUT阵列,3D堆叠与使用倒装芯片键合技术的前端ic。该成像系统能够捕获实时体积超声数据,并显示2D和3D超声图像。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
3D volumetric ultrasound imaging with a 32×32 CMUT array integrated with front-end ICs using flip-chip bonding technology
3D ultrasound imaging is becoming increasingly prevalent in the medical field. Compared to conventional 2D imaging systems, 3D imaging can provide a detailed view of tissue structures that makes diagnosis easier for the physicians. In addition, 2D image slices can be formed at various orientations to the transducer, making the examination less dependent on the skill of the sonographer. However, various challenges exist in developing a 3D imaging system, such as integration of a large number of elements, as well as post-processing of datasets received from a large number of channels. 2D transducer arrays are typically integrated with custom ICs in the probe handle to perform some intermediate beamforming and to reduce the number of cable connections to the imaging system. Capacitive micromachined ultrasonic transducers (CMUTs) have emerged as an alternative to piezoelectric transducers. Being a MEMS device, they greatly benefit from flexibility and ease of fabrication, and can be seamlessly integrated with electronics. Previous work demonstrates 3D stacking of CMUTs and dummy ICs with an intermediate interposer layer. However, that represents more of a mechanical demonstration of 3D integration. In this paper, we present a fully functional 3D ultrasound imaging system comprising a 32×32 2D CMUT array, 3D-stacked with front-end ICs using flip-chip bonding technology. The imaging system is capable of capturing real-time volumetric ultrasound data, and displaying 2D and 3D ultrasound images.
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