4.7 Article

Rapid quantification of 3D ultrasound fields with wavefront sensing and Schlieren tomography

Journal

ULTRASONICS
Volume 135, Issue -, Pages -

Publisher

ELSEVIER
DOI: 10.1016/j.ultras.2023.107115

Keywords

Schlieren technique; Ultrasound characterization; Wavefront sensing; Tomography; Three-dimensional pressure field

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By combining wavefront sensing and Schlieren tomography, the rapid and direct quantification of 3D pressure fields can be achieved without the need for extensive calibration steps. By simultaneously capturing optical phase and intensity information using a Wavefront Sensor and Schlieren projections, 3D pressure fields can be reconstructed within a few seconds. The feasibility and accuracy of this approach have been demonstrated by comparing the results with calibrated hydrophone measurements and simulations.
The rapid and precise characterization of three-dimensional (3D) pressure fields inside water is paramount for ultrasound (US) applications in fields as relevant as biomedicine and acoustic trapping. The most conventional way is to scan point-by-point a needle hydrophone across the field of interest, which is an intrinsically invasive and slow process. With typical acquisition times of hours and even days, this method remains impractical in many realistic scenarios. Alternatively, optical techniques can be used to non-invasively and rapidly measure the changes in light intensity or phase induced by pressure differences. However, these techniques remain largely qualitative: extracting precise pressure values can require extensive calibration, and complex processing, or can be limited to low-pressure ranges. Here, we report how combining wavefront sensing and Schlieren tomography enables rapid and direct quantification of 3D pressure fields while obviating any calibration steps. By simultaneously capturing optical phase and intensity information of the US-perturbed fluid using a Wavefront Sensor and Schlieren projections, respectively, 3D pressure fields over several millimeters cubic can be reconstructed after a few seconds. We present a detailed description of the approach and prove its feasibility by characterizing the US field after an acoustic lens, which is in excellent agreement with calibrated hydrophone measurements and simulations. These results are a significant step forward toward the precise and real-time characterization of ultrasound patterns.

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