利用广角衍射建模扩展医学超声中的抛物线近似的应用。
Extending the Utility of the Parabolic Approximation in Medical Ultrasound Using Wide-Angle Diffraction Modeling.
出版信息
IEEE Trans Ultrason Ferroelectr Freq Control. 2017 Apr;64(4):679-687. doi: 10.1109/TUFFC.2017.2654125. Epub 2017 Jan 16.
Abstract
Wide-angle parabolic models are commonly used in geophysics and underwater acoustics but have seen little application in medical ultrasound. Here, a wide-angle model for continuous-wave high-intensity ultrasound beams is derived, which approximates the diffraction process more accurately than the commonly used Khokhlov-Zabolotskaya-Kuznetsov (KZK) equation without increasing implementation complexity or computing time. A method for preventing the high spatial frequencies often present in source boundary conditions from corrupting the solution is presented. Simulations of shallowly focused axisymmetric beams using both the wide-angle and standard parabolic models are compared to assess the accuracy with which they model diffraction effects. The wide-angle model proposed here offers improved focusing accuracy and less error throughout the computational domain than the standard parabolic model, offering a facile method for extending the utility of existing KZK codes.
摘要
广角抛物模型在地球物理学和水下声学中得到了广泛应用,但在医学超声中应用较少。本文推导了一种用于连续波高强度超声束的广角模型,与常用的 Khokhlov-Zabolotskaya-Kuznetsov(KZK)方程相比,该模型能更精确地逼近衍射过程,而不会增加实现复杂度或计算时间。本文还提出了一种防止源边界条件中高频出现的方法,防止其破坏解。本文比较了使用广角和标准抛物模型模拟浅聚焦轴对称束的结果,以评估它们对衍射效应建模的准确性。与标准抛物模型相比,本文提出的广角模型在整个计算域中具有更高的聚焦精度和更小的误差,为扩展现有 KZK 代码的应用提供了一种简单的方法。
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