Title :
A Gaussian framework for modeling effects of frequency-dependent attenuation, frequency-dependent scattering, and gating
Author_Institution :
Center for Devices & Radiol. Health, US Food & Drug Adm., Rockville, MD, USA
Abstract :
For a wide range of applications in medical ultrasound, power spectra of received signals are approximately Gaussian. It has been established previously that an ultrasound beam with a Gaussian spectrum propagating through a medium with linear attenuation remains Gaussian. In this paper, Gaussian transformations are derived to model the effects of scattering (according to a power law, as is commonly applicable in soft tissues, especially over limited frequency ranges) and gating (with a Hamming window, a commonly used gate function). These approximations are shown to be quite accurate even for relatively broad band systems with fractional bandwidths approaching 100%. The theory is validated by experiments in phantoms consisting of glass particles suspended in agar.
Keywords :
Gaussian distribution; biological tissues; biomedical ultrasonics; phantoms; Gaussian model; Hamming window; agar suspension; frequency-dependent attenuation; frequency-dependent scattering; gating; glass particles; linear attenuation; medical ultrasound; phantom; power law; power spectra; soft tissue; Attenuation; Bandwidth; Biological tissues; Frequency; Glass; Imaging phantoms; Particle scattering; Power system modeling; Ultrasonic imaging; Windows; Agar; Artifacts; Computer Simulation; Glass; Image Enhancement; Linear Models; Models, Biological; Models, Statistical; Normal Distribution; Phantoms, Imaging; Quality Control; Scattering, Radiation; Signal Processing, Computer-Assisted; Ultrasonography;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
DOI :
10.1109/TUFFC.2002.1049739
