Litcius/Paper detail

Nonlinear ultrasound simulation in an axisymmetric coordinate system using a <i>k</i>-space pseudospectral method

Bradley E. Treeby, Elliott S. Wise, Filip Kuklis, Jiří Jaroš, Ben Cox

2020The Journal of the Acoustical Society of America42 citationsDOIOpen Access PDF

Abstract

A full-wave model for nonlinear ultrasound propagation through a heterogeneous and absorbing medium in an axisymmetric coordinate system is developed. The model equations are solved using a nonstandard or k-space pseudospectral time domain method. Spatial gradients in the axial direction are calculated using the Fourier collocation spectral method, and spatial gradients in the radial direction are calculated using discrete trigonometric transforms. Time integration is performed using a k-space corrected finite difference scheme. This scheme is exact for plane waves propagating linearly in the axial direction in a homogeneous and lossless medium and significantly reduces numerical dispersion in the more general case. The implementation of the model is described, and performance benchmarks are given for a range of grid sizes. The model is validated by comparison with several analytical solutions. This includes one-dimensional absorption and nonlinearity, the pressure field generated by plane-piston and bowl transducers, and the scattering of a plane wave by a sphere. The general utility of the model is then demonstrated by simulating nonlinear transcranial ultrasound using a simplified head model.

Topics & Concepts

Mathematical analysisNonlinear systemPhysicsPseudo-spectral methodCylindrical coordinate systemCartesian coordinate systemFourier transformMathematicsGeometryFourier analysisQuantum mechanicsPhotoacoustic and Ultrasonic ImagingUltrasound Imaging and ElastographyUltrasonics and Acoustic Wave Propagation
Nonlinear ultrasound simulation in an axisymmetric coordinate system using a <i>k</i>-space pseudospectral method | Litcius