<![CDATA[Modelling nonlinear ultrasound propagation in absorbing media using the k-Wave toolbox: Experimental validation]]>

2026-06-03T14:39:51Z https://api.figshare.com/v2/oai

oai:figshare.com:article/20005562 2022-06-08T12:58:56Z category_30142 portal_549 item_type_3 month_year_06_2022

10.5522/04/20005562.v1 https://figshare.com/articles/dataset/Modelling_nonlinear_ultrasound_propagation_in_absorbing_media_using_the_k-Wave_toolbox_Experimental_validation/20005562 https://ndownloader.figshare.com/files/35609060 https://ndownloader.figshare.com/files/35609063 https://ndownloader.figshare.com/files/35609069 https://ndownloader.figshare.com/files/35609072 https://ndownloader.figshare.com/files/35609075 10.1109/ULTSYM.2012.0130 Wang, Kejia Kejia Wang Teoh, Emily Emily Teoh Jaros, Jiri Jiri Jaros Treeby, Bradley Bradley Treeby <![CDATA[Modelling nonlinear ultrasound propagation in absorbing media using the k-Wave toolbox: Experimental validation]]> Acoustics and acoustical devices; waves Hydrophone measurement Diagnostic imaging transducer Nonlinear propagation Planar scan Homogeneous Medium Soft tissue mimicking medium Olive oil Acoustics and Acoustical Devices; Waves 2022-06-08 2023-06-05 Dataset 2022 University College London This data was collected to validate simulations performed using the k-Wave toolbox when the wave propagation is nonlinear and the medium is absorbing.

Experiments were conducted using a diagnostic ultrasound scanner (Sonix RP, Ultrasonix) with a linear array probe (L9-4/38) in both water and olive oil. Measurements were performed using a two-axis automated scanning tank with a 0.4 mm membrane hydrophone.

The coordinate system used is as follows: X is the elevation direction relative to the transducer (out-of-plane), Y is the lateral (in-plane) direction, Z is the axial direction.

In total, this study contains 12 datasets contained in 4 files as follows.

File 1. X-Y scans of transducer in water with no steering (4 datasets with planes measured at 1.3, 11.1, 21.3, and 31.3 mm from the transducer).

File 2. X-Y scans of transducer in water with a steering angle of 20 degrees (2 datasets with planes measured at 1.3 and 21.3 mm from the transducer).

File 3. Y-Z scans of the transducer in water with steering angles of 0 (no steering) and 20 degrees (2 datasets).

File 4. X-Y scans of transducer in olive oil with no steering (4 datasets with planes measured at 2.4, 12.4, 22.4, 32.4 mm from the transducer).

A MATLAB script is provided to produce simple summary plots of the data.

Notes:

For all X-Y scans, the reported Z-positions are approximate. Z-alignment was performed using a manual translation stage, and the position of the transducer relative to the hydrophone in the first scan plane was estimated using a diagnostic ultrasound image. A more accurate estimate could potentially be obtained using the time-of-flight data for the recorded waveforms.

For dataset 3, the reported X-Y coordinate origin for the scan plane at 2.39mm (dataset1) is not aligned with the X-Y coordinate origin for the other scan planes (dataset2, dataset3, dataset4). This could potentially be corrected, e.g., using acoustic holography and aligning the projections to the measured planes.

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