Signal processing strategies in acoustic elastography

Author

Insana, M.F. ; Biegen, M. ; Chaturvedi, P. ; Hall, T.J. ; Bertrand, M.

Author_Institution

Dept. of Radiol., Kansas Univ. Med. Center, Kansas City, KS, USA

Volume

2

fYear

1996

fDate

3-6 Nov 1996

Firstpage

1139

Abstract

Elastography is a remote sensing technique for imaging the elastic properties of biological tissues. An essential feature is tissue deformation (strain) that is measured by cross correlating ultrasonic echo waveforms acquired before and after a weak static compression. To fully exploit the large object contrast available among body tissues, many dependent experimental parameters must be carefully adjusted. This paper outlines a strategy for selecting the applied stress field including boundary conditions, transducer frequency and bandwidth, and echo window length and overlap that minimize elastographic noise and maximize dynamic range for a given spatial resolution

Keywords

acoustic correlation; acoustic noise; biomechanics; biomedical ultrasonics; echo; elasticity; image resolution; medical image processing; acoustic elastography; applied stress field; bandwidth; biological tissues; body tissues; boundary conditions; cross correlation; dynamic range; echo window length; elastic properties; elastographic noise; imaging; large object contrast; remote sensing technique; signal processing strategies; spatial resolution; strain; tissue deformation; transducer frequency; ultrasonic echo waveforms; weak static compression; Acoustic imaging; Acoustic measurements; Acoustic signal processing; Biological tissues; Biomedical signal processing; Remote sensing; Strain measurement; Stress; Ultrasonic imaging; Ultrasonic variables measurement;

fLanguage

English

Publisher

ieee

Conference_Titel

Ultrasonics Symposium, 1996. Proceedings., 1996 IEEE

Conference_Location

San Antonio, TX

ISSN

1051-0117

Print_ISBN

0-7803-3615-1

Type

conf

DOI

10.1109/ULTSYM.1996.584192

Filename

584192