DocumentCode
1052533
Title
Comparison of stress field forming methods for vibro-acoustography
Author
Chen, Shigao ; Fatemi, Mostafa ; Kinnick, Randall ; Greenleaf, James F.
Author_Institution
Dept. of Physiol. & Biophys., Basic Ultrasound Res. Lab., Rochester, MN, USA
Volume
51
Issue
3
fYear
2004
fDate
3/1/2004 12:00:00 AM
Firstpage
313
Lastpage
321
Abstract
Vibro-acoustography is a method that produces images of the acoustic response of a material to a localized harmonic motion generated by ultrasound radiation force. The low-frequency, oscillatory radiation force (e.g., 10 kHz) is produced by amplitude modulating a single ultrasound beam, or by interfering two beams of slightly different frequencies. Proper beam forming for the stress field of the probing ultrasound is very important because it determines the resolution of the imaging system. Three beam-forming geometries are studied: amplitude modulation, confocal, and x-focal. The amplitude of radiation force on a unit point target is calculated from the ultrasound energy density averaged over a short period of time. The profiles of radiation stress amplitude oil the focal plane and on the beam axis are derived. The theory is validated by experiments using a small sphere as a point target. A laser vibrometer is used to measure the velocity of the sphere, which is proportional to the radiation stress exerted on the target as the transducer is scanned over the focal plane or along the beam axis. The measured velocity profiles match the theory. The theory and experimental technique may be useful in future transducer design for vibro-acoustography.
Keywords
amplitude modulation; bioacoustics; biological tissues; biomedical ultrasonics; ultrasonic imaging; 10 kHz; amplitude modulation; beam axis; beam forming geometries; focal plane; laser vibrometer; localized harmonic motion; oscillatory radiation force; radiation force; radiation stress amplitude; stress field forming methods; transducer; ultrasound beam; ultrasound energy density; ultrasound radiation force; unit point target; velocity profiles; vibroacoustography; Acoustic beams; Acoustic materials; Amplitude modulation; Frequency; Laser beams; Optical modulation; Stress; Transducers; Ultrasonic imaging; Velocity measurement; Acoustics; Computer Simulation; Connective Tissue; Elasticity; Equipment Design; Models, Biological; Phantoms, Imaging; Stress, Mechanical; Tomography; Transducers; Ultrasonography; Vibration;
fLanguage
English
Journal_Title
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
Publisher
ieee
ISSN
0885-3010
Type
jour
DOI
10.1109/TUFFC.2004.1320787
Filename
1320787
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