Variation of ultrasound image lateral spectrum with assumed speed of sound and true scatterer density

Abstract

One method of estimating sound speed in diagnostic ultrasound imaging consists of choosing the speed of sound that generates the sharpest image, as evaluated by the lateral frequency spectrum of the squared B-mode image. In the current work, simulated and experimental data on a typical (47mm aperture, 3.3–10.0MHz response) linear array transducer are used to investigate the accuracy of this method. A range of candidate speeds of sound (1240–1740m/s) was used, with a true speed of sound of 1490m/s in simulations and 1488m/s in experiments. Simulations of single point scatterers and two interfering point scatterers at various locations with respect to each other gave estimate errors of 0.0–2.0%. Simulations and experiments of scatterer distributions with a mean scatterer spacing of at least 0.5mm gave estimate errors of 0.1–4.0%. In the case of lower scatterer spacing, the speed of sound estimates become unreliable due to a decrease in contrast of the sharpness measure between different candidate speeds of sound. This suggests that in estimating speed of sound in tissue, the region of interest should be dominated by a few, sparsely spaced scatterers. Conversely, the decreasing sensitivity of the sharpness measure to speed of sound errors for higher scatterer concentrations suggests a potential method for estimating mean scatterer spacing.