Fast simulation of realistic pseudo-acoustic nonlinear radio-frequency ultrasound images

2014 IEEE International Ultrasonics Symposium Pub Date : 2014-10-23 DOI:10.1109/ULTSYM.2014.0552

F. Varray, H. Liebgott, C. Cachard, D. Vray

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引用次数: 2

Abstract

In the medical ultrasound (US) community, only few simulators are able to fully simulate nonlinear wave propagation. In our recently developed software Creanuis [1], realistic nonlinear radio-frequency US images can be simulated. Unfortunately, the rather long computation time represents an important limitation, and is far from being comparable with the fastest simulation tools based on convolution strategies. In this work, a strategy combining Creanuis with a convolution appoach is proposed. This pseudo-acoustic nonlinear image strategy (PANIS) produces linear as well as nonlinear images. It consists to first simulate a set of punctual scatterers to locally extract a nonlinear point-spread function (PSF). Then, the 2D convolution of each of these PSF and the full medium is performed. The final PANIS image is obtained by selecting the specific part of each elementary convolved images. This final image contains the whole spectrum evolution with a depth dependent resolution and signal-to-noise ratio. The root-mean square error, between the statistics of PANIS and Creanuis images is kept under 1% and validates the model. The computation time is kept under 10 secondes for the convolution part.

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真实伪声非线性射频超声图像的快速仿真

在医学超声(美国)界，只有少数模拟器能够完全模拟非线性波的传播。在我们最近开发的Creanuis软件[1]中，可以模拟真实的非线性射频US图像。不幸的是，相当长的计算时间代表了一个重要的限制，并且远远不能与基于卷积策略的最快的模拟工具相比较。在这项工作中，提出了一种将Creanuis与卷积方法相结合的策略。这种伪声学非线性图像策略(PANIS)可以产生线性和非线性图像。首先模拟一组准时散射体，局部提取非线性点扩散函数(PSF)。然后，执行这些PSF和整个介质的二维卷积。通过选取各初等卷积图像的特定部分，得到最终的PANIS图像。最终的图像包含了与深度相关的分辨率和信噪比的整个频谱演变。PANIS和Creanuis图像统计的均方根误差保持在1%以下，验证了模型的有效性。卷积部分的计算时间保持在10秒以下。

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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2014 IEEE International Ultrasonics Symposium

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