A method for the geometric calibration of ultrasound transducer arrays with arbitrary geometries

Abstract

Geometric calibration of ultrasound transducer arrays is critical to optimizing the performance of photoacoustic computed tomography (PACT) systems. We present a geometric calibration method that is applicable to a wide range of PACT systems. We obtain the speed of sound and point source locations using surrogate methods, which results in a linear problem in the transducer coordinates. We characterize the estimation error, which informs our choice of the point source arrangement. We demonstrate our method in a three-dimensional PACT system and show that our method improves the contrast-to-noise ratio, the size, and the spread of point source reconstructions by $\left(80\pm 19\right)\%$, $\left(19\pm 3\right)\%$, and $\left(7\pm 1\right)\%$, respectively. We reconstruct the images of a healthy human breast before and after calibration and find that the calibrated image reveals vasculatures that were previously invisible. Our work introduces a method for geometric calibration in PACT and paves the way for improving PACT image quality.

Keywords: Geometric calibration; Photoacoustic imaging; Position estimation; Ultrasound transducer arrays.