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Depth-of-field enhancement in Filtered-Delay Multiply and Sum beamformed images using Synthetic Aperture Focusing

•F-DMAS beamforming performance with Synthetic Aperture Focusing (SAF) is analyzed.•Both Synthetic Transmit Aperture (STA) and monostatic SAF techniques are tested.•Results of simulations, experimental phantom and in vivo scans are presented.•Images show that with F-DMAS and STA a higher quality is...

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Bibliographic Details
Published in:Ultrasonics 2017-03, Vol.75, p.216-225
Main Authors: Matrone, Giulia, Savoia, Alessandro Stuart, Caliano, Giosuè, Magenes, Giovanni
Format: Article
Language:English
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Summary:•F-DMAS beamforming performance with Synthetic Aperture Focusing (SAF) is analyzed.•Both Synthetic Transmit Aperture (STA) and monostatic SAF techniques are tested.•Results of simulations, experimental phantom and in vivo scans are presented.•Images show that with F-DMAS and STA a higher quality is achieved at all depths.•Good results can be also obtained with simple monostatic SAF and F-DMAS. The Synthetic Aperture Focusing (SAF) technique makes it possible to achieve a higher and more uniform quality of ultrasound images throughout depth, as if both transmit and receive dynamic focusing were applied. In this work we combine a particular implementation of SAF, called Synthetic Transmit Aperture (STA) technique, in which a single element in turn transmits and all the array elements receive the ultrasound wave, with the Filtered-Delay Multiply and Sum (F-DMAS) non-linear beamforming algorithm that we presented in a previous paper. We show that using F-DMAS, which is based on a measure of backscattered signal spatial correlation, B-mode images have a higher contrast resolution but suffer from a loss of brightness away from the transmit focus, when a classical scan with receive-only dynamic focusing is performed. On the other hand, when synthetic transmit focusing is achieved by implementing STA, such a loss is compensated for and a higher depth of field is obtained, as signal coherence improves. A drawback of SAF/STA however is the reduced signal-to-noise ratio, due to single-element transmission; in the paper we also analyze how this influences F-DMAS images. Finally, a preliminary investigation on the use of the classical monostatic SAF technique with F-DMAS beamforming is also carried out to evaluate its potential performances.
ISSN:0041-624X
1874-9968
DOI:10.1016/j.ultras.2016.11.022