Experimental Validation of k-Wave: Nonlinear Wave Propagation in Layered, Absorbing Fluid Media

• https://ieeexplore.ieee.org/document/8839830

Computational modelling, full-wave modelling, model checking, model validation,
pressure measurement, ultrasonic transducers.

Models of ultrasound propagation in biologically relevant media have applications
in planning and verification of ultrasound therapies and computational dosimetry.
To be effective, the models must be able to accurately predict both the spatial
distribution and amplitude of the acoustic pressure. This requires that the
models are validated in absolute terms, which for arbitrarily heterogeneous media
should be performed by comparison with measurements of the acoustic field. In
this study, simulations performed using the open-source k-Wave acoustics toolbox
were quantitatively validated against measurements of acoustic pressure in water
and heterogeneous absorbing fluid media. In water, the measured and simulated
spatial peak pressures agreed to within 3% under linear conditions, and 7% under
non-linear conditions. After propagation through a planar or wedge shaped
glycerol filled phantom, the difference in spatial peak pressure was 7% and 6%
respectively. These differences are within the expected uncertainty of the
acoustic pressure measurement. The -6 dB width and length of the focus agreed to
within 3% in all cases, and the focal positions were within 0.1 mm for the planar
phantom and 1.1 mm for the wedge shaped phantom. These results demonstrate that
when the acoustic medium properties and geometry are well known, accuarate
quantitative predictions of the acoustic field can be made using k-Wave.

• pdf TUFFC202020.pdf 2 MB