Abstract
A shift of paradigm is currently underway in biomedical ultrasound thanks to plane or diverging waves coherent compounding for faster imaging. One remaining challenge consists in handling phase and amplitude aberrations induced during the ultrasonic propagation through complex layers. Unlike conventional line-per-line imaging, ultrafast ultrasound provides backscattering information from the whole imaged area for each transmission. Here, we take benefit from this feature and propose an efficient approach to perform fast aberration correction. Our method is based on the Singular Value Decomposition (SVD) of an ultrafast compound matrix containing backscattered data for several plane wave transmissions. First, we explain the physical signification of SVD and associated singular vectors within the ultrafast matrix formalism. We theoretically demonstrate that the separation of spatial and angular variables, rendered by SVD on ultrafast data, provides an elegant and straightforward way to optimize the angular coherence of backscattered data. In heterogeneous media, we demonstrate that the first spatial and angular singular vectors retrieve respectively the non-aberrated image of a region of interest, and the phase and amplitude of its aberration law. Numerical, in vitro and in vivo results prove the efficiency of the image correction, but also the accuracy of the aberrator determination. Based on spatial and angular coherence, we introduce a complete methodology for adaptive beamforming of ultrafast data, performed on successive isoplanatism patches undergoing SVD beamforming. The simplicity of this method paves the way to real-time adaptive ultrafast ultrasound imaging and provides a theoretical framework for future quantitative ultrasound applications.
Highlights
A LTHOUGH ultrasound imaging is a mature medical imaging tool, new techniques are constantly explored to further improve image quality and extend its clinicalManuscript received February 28, 2020; revised March 25, 2020; accepted April 4, 2020
If one computes the angular coherence in speckle for a casual B-mode image, limited to a control region, the obtained matrix exhibits a triangle profile: covariance is maximal along the diagonal – auto-coherence - and vanishes linearly down to zero when the angular spacing increases (Fig. 3)
After Singular Value Decomposition (SVD) filtering of the image, this effect is totally recovered, and even further since the angular coherence of each block is constant equal to 1. Even if this result seems certain mathematically, it illustrates that the SVD provides an image, for which all pixels are being seen the same way by all transmit angles
Summary
A LTHOUGH ultrasound imaging is a mature medical imaging tool, new techniques are constantly explored to further improve image quality and extend its clinical. Manuscript received February 28, 2020; revised March 25, 2020; accepted April 4, 2020. Date of publication April 13, 2020; date of current version September 30, 2020. Color versions of one or more of the figures in this article are available online at http://ieeexplore.ieee.org. The first objective of Ultrasound imaging is to build an accurate image of the medium from ultrasonic backscattered signals through a process called beamforming
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