A new approach to calculating spatial impulse responses

J. A. Jensen
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引用次数: 24

Abstract

Using linear acoustics the emitted and scattered ultrasound field can be found by using spatial impulse responses as developed by Tupholme (1969) and Stepanishen (1971). The impulse response is calculated by the Rayleigh integral by summing the spherical waves emitted from all of the aperture surface. The evaluation of the integral is cumbersome and quite involved for different aperture geometries. This paper re-investigates the problem and shows that the field can be found from the crossings between the boundary of the aperture and a spherical wave emitted from the field point onto the plane of the emitting aperture. Summing the angles of the arcs within the aperture readily yields the spatial impulse response for a point in space. The approach makes is possible to make very general calculation routines for arbitrary, flat apertures in which the outline of the aperture is either analytically or numerically defined. The exact field can then be found without evaluating any integrals by merely finding the zeros of the either the analytic or numerically defined functions. This makes it possible to describe the transducer surface using an arbitrary number of lines for the boundary. The approach can also be used for finding analytic solutions to the spatial impulse response for new geometries of, for example, ellipsoidal shape. The approach also makes it easy to incorporate any apodization function and the effect from different transducers baffle mountings. Examples of spatial impulse responses for a shape made from lines bounding the aperture is shown along with solutions for Gaussian apodized round transducer.
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一种计算空间脉冲响应的新方法
利用线性声学,可以利用Tupholme(1969)和Stepanishen(1971)开发的空间脉冲响应来发现发射和散射的超声场。脉冲响应由瑞利积分计算,通过将所有孔径表面发射的球面波求和。对于不同的孔径几何形状,积分的计算是非常繁琐和复杂的。本文对这一问题进行了重新研究,提出了从场点发射到发射孔平面上的球面波与孔径边界的交点处可以找到场。将孔径内的圆弧角度相加,很容易得到空间中某一点的空间脉冲响应。这种方法使得对任意的平面孔径进行非常一般的计算成为可能,其中孔径的轮廓要么是解析的,要么是数值的。这样就可以找到精确的场,而不需要计算任何积分,只需找到解析函数或数值定义函数的零点。这使得用任意数目的线作为边界来描述换能器表面成为可能。该方法也可用于寻找新的几何形状的空间脉冲响应的解析解,例如椭球形状。这种方法也使得它很容易纳入任何apodiization功能和效果从不同的换能器挡板安装。给出了由包围孔径的线构成的形状的空间脉冲响应的例子,并给出了高斯apodized圆形换能器的解。
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