Reconstructing effective ultrasound transducer models via distributed source inversion
Abstract
Accurate modeling of ultrasound wave propagation is essential for high-fidelity simulation and imaging in ultrasonic testing. A primary challenge lies in characterizing the excitation source, particularly for transducers with large apertures relative to the acoustic wavelengths. In such cases, non-uniform excitation and spatial interference significantly affect the resulting radiation patterns. This paper proposes a distributed source inversion strategy to reconstruct an effective spatio-temporal transducer model that reproduces experimentally measured wavefields. The reconstructed source model captures aperture-dependent phase and amplitude variations without the need for detailed knowledge of the transducer structure. The approach is validated using directivity measurements on an aluminum half-cylinder, where simulations incorporating the reconstructed source model show close agreement with experimental directivity patterns and waveform shapes. Finally, synthetic studies on reverse time migration and full-waveform inversion demonstrate that accurate transducer modeling is critical for the success of simulation-based imaging and inversion workflows and significantly improves reconstruction quality.
Cite
@article{arxiv.2603.24415,
title = {Reconstructing effective ultrasound transducer models via distributed source inversion},
author = {Tim Bürchner and Simon Schmid and Ernst Rank and Stefan Kollmannsberger and Andreas Fichtner},
journal= {arXiv preprint arXiv:2603.24415},
year = {2026}
}
Comments
11 pages, 11 figures