A 35 MHz linear ultrasonic array for medical imaging

Proceedings of the 13th IEEE International Symposium on Applications of Ferroelectrics, 2002. ISAF 2002. Pub Date : 2002-05-28 DOI:10.1109/ISAF.2002.1195939

J. Cannata, T. Shrout, K. Shung

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引用次数: 5

Abstract

Ultrasound backscatter microscope (UBM) imaging systems operating above 20 MHz are capable of achieving the axial and lateral resolutions needed for applications in ophthalmology and dermatology. Unfortunately these systems rely upon mechanically scanned single element transducers and suffer from a fixed focus, low frame rate and cumbersome scanning hardware. High frequency arrays are therefore desirable for several reasons, including the ability to dynamically focus the sound beam, increase frame rates and clinical convenience. This study investigates the design tradeoffs involved in the development of a high frequency (35 MHz) 64-element linear array. This array was designed primarily for human eye and skin imaging, and features monolithic elements mechanically diced out of a fine grain high density PZT-5H ceramic. Array elements were spaced with a 50 /spl mu/m pitch, interconnected via a flexible circuit and matched to the 50 /spl Omega/ system electronics via a 85 /spl Omega/ transmission line coaxial cable. Several prototype arrays were constructed with promising results. An average center frequency of 34 MHz with a -6 dB bandwidth of at least 45% per element was achieved. The maximum combined electrical and acoustical crosstalk for nearest and next nearest elements was less than -29 dB, and the average 40 dB pulse length was 105 ns.

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用于医学成像的35 MHz线性超声阵列

工作在20兆赫以上的超声后向散射显微镜(UBM)成像系统能够实现眼科和皮肤病学应用所需的轴向和横向分辨率。不幸的是，这些系统依赖于机械扫描的单元件传感器，并且受到固定焦点，低帧率和笨重的扫描硬件的影响。因此，出于几个原因，高频阵列是可取的，包括动态聚焦声束的能力，提高帧率和临床便利性。本研究探讨了开发高频(35 MHz) 64元线性阵列所涉及的设计权衡。该阵列主要是为人眼和皮肤成像而设计的，其特点是采用细颗粒高密度PZT-5H陶瓷机械切割而成的单片元件。阵列元件间距为50 /spl μ /m，通过柔性电路互连，并通过85 /spl ω /传输线同轴电缆与50 /spl ω /系统电子设备匹配。构建了几个原型阵列，并取得了令人满意的结果。平均中心频率为34 MHz，每个元件的-6 dB带宽至少为45%。最近和次最近元件的最大电声串扰小于-29 dB，平均40 dB脉冲长度为105 ns。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the 13th IEEE International Symposium on Applications of Ferroelectrics, 2002. ISAF 2002.

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