A new extended range ultrasonic synthetic aperture tissue harmonic imaging system

Tissue harmonic imaging(THI) has been widely used in the diagnostic ultrasonic imaging system thanks to its benefits such as lowered artifacts and improved contrast resolution. Recently we reported that the THI can be successfully combined with synthetic aperture imaging(SAI) to improve the signal-t...

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Hauptverfasser:	Moo-Ho Bae, Sung-Bae Park, Han-Woo Lee, Sang-Gyu Nam, Mok-Kun Jeong
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Acoustics Apertures extended range Harmonic analysis Imaging Probes Signal to noise ratio synthetic aperture imaging tissue harmonic imaging Ultrasonic imaging
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creator	Moo-Ho Bae Sung-Bae Park Han-Woo Lee Sang-Gyu Nam Mok-Kun Jeong
description	Tissue harmonic imaging(THI) has been widely used in the diagnostic ultrasonic imaging system thanks to its benefits such as lowered artifacts and improved contrast resolution. Recently we reported that the THI can be successfully combined with synthetic aperture imaging(SAI) to improve the signal-to-noise ratio(SNR) of the THI. Nevertheless, conversion of the propagating ultrasound in the tissue to the harmonic component is concentrated mainly around the transmission(Tx) focal point. This limits the effective imaging range of the THI. In order to mitigate this issue, we propose new SAI methods which utilize distributed virtual sources to spread out the conversion of harmonic components of the propagating wave. As an example, two new SAI methods are proposed, where one method maximizes SNR with cost of frame rate, while the other method compromises SNR and frame rate. The usefulness of these methods is verified through computer simulations using both PZFlex and Field II, and the results show that the proposed methods can extend the effective range successfully.
doi_str_mv	10.1109/ULTSYM.2011.0096
format	Conference Proceeding
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subjects	Acoustics Apertures extended range Harmonic analysis Imaging Probes Signal to noise ratio synthetic aperture imaging tissue harmonic imaging Ultrasonic imaging
title	A new extended range ultrasonic synthetic aperture tissue harmonic imaging system
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