Title :
Multielement synthetic transmit aperture imaging using temporal encoding
Author :
Gammelmark, Kim Løkke ; Jensen, Jørgen Arendt
Author_Institution :
Center for Fast Ultrasound Imaging, Tech. Univ. of Denmark, Lyngby, Denmark
fDate :
4/1/2003 12:00:00 AM
Abstract :
A new method to increase the signal-to-noise ratio (SNR) of synthetic transmit aperture imaging is investigated. The approach utilizes multiple elements to emulate a spherical wave, and the conventional short excitation pulse is replaced by a linear frequency-modulated (FM) signal. The approach is evaluated in terms of image quality parameters in comparison to linear array imaging. Field II simulations using an 8.5-MHz linear array transducer with 128 elements show an improvement in lateral resolution of up to 30% and up to 10.75% improvement in contrast resolution for the new approach. Measurements are performed using our experimental multichannel ultrasound scanning system, RASMUS. The designed linear FM signal obtains temporal sidelobes below -55 dB, and SNR investigations show improvements of 4-12 dB. A 30 mm (≈45%) increase in penetration depth is obtained on a multitarget phantom with 0.5 dB/[cm MHz] attenuation. Furthermore, in vivo images of the abdomen are presented, which demonstrate the clinical application of the new approach.
Keywords :
biomedical transducers; biomedical ultrasonics; frequency modulation; image coding; image resolution; medical image processing; phantoms; ultrasonic transducer arrays; 8.5 MHz; RASMUS; SNR investigations; abdomen; clinical application; contrast resolution; conventional short excitation pulse; designed linear FM signal; field II simulations; image quality parameters; in vivo images; lateral resolution; linear array imaging; linear array transducer; linear frequency-modulated signal; multichannel ultrasound scanning system; multielement synthetic transmit aperture imaging; multiple elements; multitarget phantom; penetration depth; signal-to-noise ratio; spherical wave; temporal encoding; temporal sidelobes; Encoding; Frequency; Image quality; Performance evaluation; Signal design; Signal resolution; Signal to noise ratio; Ultrasonic imaging; Ultrasonic transducers; Ultrasonic variables measurement; Abdomen; Adult; Algorithms; Artifacts; Computer Simulation; Cysts; Equipment Design; Humans; Image Enhancement; Male; Models, Biological; Motion; Phantoms, Imaging; Quality Control; Reproducibility of Results; Scattering, Radiation; Sensitivity and Specificity; Ultrasonography;
Journal_Title :
Medical Imaging, IEEE Transactions on
DOI :
10.1109/TMI.2003.809088
