Fast simulation of non-linear pulsed ultrasound fields using an angular spectrum approach

A fast non-linear pulsed ultrasound field simulation is presented. It is implemented based on an angular spectrum approach (ASA), which analytically solves the non-linear wave equation. The ASA solution to the Westervelt equation is derived in detail. The calculation speed is significantly increased compared to a numerical solution using an operator splitting method (OSM). The ASA has been modified and extended to pulsed non-linear ultrasound fields in combination with Field II, where any array transducer with arbitrary geometry, excitation, focusing and apodization can be simulated. The accuracy of the non-linear ASA is compared to the non-linear simulation program – Abersim, which is a numerical solution to the Burgers equation based on the OSM. Simulations are performed for a linear array transducer with 64 active elements, focus at 40 mm, and excitation by a 2-cycle sine wave with a center frequency of 5 MHz. The speed is increased approximately by a factor of 140 and the calculation time is 12 min with a standard PC, when simulating the second harmonic pulse at the focal point. For the second harmonic point spread function the full width error is 1.5% at −6 dB and 6.4% at −12 dB compared to Abersim.

► Non-linear ultrasound fields was modeled using an angular spectrum approach.
► Field II was used to generate the source of angular spectrum approach.
► The second harmonic pulsed ultrasound field has been simulated using Matlab.
► The simulated results was compared to the Abersim results.
► The simulation accuracy is guaranteed and the calculation speed is increased.