Laboratory of Mechanics and Acoustics, UPR CNRS 7051, Marseille, France.
Ultrasonics. 2011 Apr;51(3):325-39. doi: 10.1016/j.ultras.2010.10.006. Epub 2010 Nov 2.
Methods of measuring ultrasonic wave velocity in an elastic sample require data on the thickness of the sample and/or the distances between the transducers and the sample. The uncertainty of the ultrasonic wave velocity measurements generally depends on that of the data available. Conversely, to determine the thickness of a material, it is necessary to have a priori information about the wave velocity. This problem is particularly hard to solve when measuring the parameters of biological specimens such as bones having a greater acoustical impedance contrast (typically 3-5 MRayl) than that of the surrounding soft tissues (typically 1.5 MRayl). Measurements of this kind cannot easily be performed. But obtaining the thickness of a bone structure and/or the ultrasonic wave velocity is a important problem, for example, in biomechanical field for the calculation of elastic modulus, or in acoustical imaging field to parameterize the images, and to reference the grey or color level set to a physical parameter. The aim of the present study was to develop a method of simultaneously and independently determining the velocity of an ultrasonic wave in an elastic sample and the wave path across the thickness of this sample, using only one acquisition in pure transmission mode. The new method, which we have called the "Wavelet-Based Processing" method, is based on the wavelet decomposition of the signals and on a suitable transmitted incident wave correlated with the experimental device, and the mathematical properties such as orthonormality, of which lend themselves well to the time-scale approach. By following an adapted algorithm, ultrasonic wave velocities in parallelepipedic plates of elastic manufactured material and the apparent thicknesses were both measured using a water tank, a mechanical device and a matched pair of 1MHz ultrasonic focused transducers having a diameter of 3mm, a focal length of 150mm and beam width of 2×2mm at the focus (mean temperature 22°). The results were compared with those obtained with a conventional Pulse-mode method and with the control values, to check their validity. Measurements performed on bovine and human dry cortical bone samples are also presented to assess the limitations of the method when it is applied to elastic biological samples, including those of an equal-wavelength size (≈1.5mm). The thicknesses and the ultrasonic wave velocities were then measured in this kind of (quasi-) parallelepipedic elastic materials with an mean estimated error ranged from 1% to 3.5% compared to the referenced values.
测量弹性样品中超声波速度的方法需要有关样品厚度和/或换能器与样品之间距离的数据。超声波速度测量的不确定度通常取决于可用数据的不确定度。相反,要确定材料的厚度,就必须事先了解波速。在测量具有比周围软组织(通常为 1.5MRayl)更大声阻抗对比度(通常为 3-5MRayl)的生物标本(如骨骼)的参数时,这个问题尤其难以解决。这种类型的测量不容易进行。但是,获取骨结构的厚度和/或超声波速度是一个重要的问题,例如在生物力学领域用于计算弹性模量,或在声学成像领域对参数化图像,以及将灰度或颜色级别设置为物理参数。本研究的目的是开发一种仅使用纯传输模式中的一次采集即可同时独立确定弹性样品中超声波速度和穿过样品厚度的波路径的方法。我们称之为“基于小波处理”的新方法基于信号的小波分解以及与实验装置相关的合适的发射入射波,以及其正交性等数学特性非常适合时-频方法。通过遵循适应的算法,使用水箱、机械装置和匹配的一对直径为 3mm、焦距为 150mm、焦点处波束宽度为 2×2mm 的 1MHz 聚焦超声换能器,测量了弹性制造材料的平行六面体板中的超声波速度和表观厚度。将结果与使用常规脉冲模式方法获得的结果以及与控制值进行比较,以验证其有效性。还介绍了对牛和人干皮质骨样本的测量结果,以评估该方法应用于弹性生物样本时的局限性,包括那些具有相等波长大小(≈1.5mm)的样本。然后在这种(准)平行六面体弹性材料中测量厚度和超声波速度,与参考值相比,平均估计误差范围为 1%至 3.5%。
