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Frequency dependence of speckle in continuous-wave ultrasound with implications for blood perfusion measurements.

Jansson, Tomas LU ; Jurkonis, Rytis ; Mast, T Douglas ; Persson, Hans W LU and Lindström, Kjell LU (2002) In IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control 49(6). p.715-725
Abstract
Speckle in continuous wave (CW) Doppler has previously been found to cause large variations in detected Doppler power in blood perfusion measurements, where a large number of blood vessels are present in the sample volume. This artifact can be suppressed by using a number of simultaneously transmitted frequencies and averaging the detected signals. To optimize the strategy, statistical properties of speckle in CW ultrasound need to be known. This paper presents analysis of the frequency separation necessary to obtain independent values of the received power for CW ultrasound using a simplified mathematical model for insonation of a static, lossless, statistically homogeneous, weakly scattering medium. Specifically, the autocovariance... (More)
Speckle in continuous wave (CW) Doppler has previously been found to cause large variations in detected Doppler power in blood perfusion measurements, where a large number of blood vessels are present in the sample volume. This artifact can be suppressed by using a number of simultaneously transmitted frequencies and averaging the detected signals. To optimize the strategy, statistical properties of speckle in CW ultrasound need to be known. This paper presents analysis of the frequency separation necessary to obtain independent values of the received power for CW ultrasound using a simplified mathematical model for insonation of a static, lossless, statistically homogeneous, weakly scattering medium. Specifically, the autocovariance function for received power is derived, which functionally is the square of the (deterministic) autocorrelation function of the effective sample volumes produced by the transducer pair for varying frequencies, at least if a delta correlated medium is assumed. A marginal broadening of the modeled autocovariance functions is expected for insonation of blood. The theory is applicable to any transducer aperture, but has been experimentally verified here with 5-MHz, 6.35-mm circular transducers using an agar phantom containing small, randomly dispersed glass particles. A similar experimental verification of a transducer used in multiple-frequency blood perfusion measurements shows that the model proposed in this paper is plausible for explaining the decorrelation between different channels in such a measurement. (Less)
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author
; ; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Rheology, Regional Blood Flow : physiology, Imaging, Phantoms, Structural, Models, Cardiovascular, Artifacts, Blood Flow Velocity, Support, Non-U.S. Gov't, Ultrasonography : methods
in
IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control
volume
49
issue
6
pages
715 - 725
publisher
IEEE - Institute of Electrical and Electronics Engineers Inc.
external identifiers
  • pmid:12075965
  • wos:000176055500005
  • scopus:0036591391
ISSN
0885-3010
DOI
10.1109/TUFFC.2002.1009330
language
English
LU publication?
yes
id
df8eefdc-3f60-464d-a252-589ad9e22aab (old id 108933)
date added to LUP
2016-04-01 11:46:01
date last changed
2022-01-26 17:56:42
@article{df8eefdc-3f60-464d-a252-589ad9e22aab,
  abstract     = {{Speckle in continuous wave (CW) Doppler has previously been found to cause large variations in detected Doppler power in blood perfusion measurements, where a large number of blood vessels are present in the sample volume. This artifact can be suppressed by using a number of simultaneously transmitted frequencies and averaging the detected signals. To optimize the strategy, statistical properties of speckle in CW ultrasound need to be known. This paper presents analysis of the frequency separation necessary to obtain independent values of the received power for CW ultrasound using a simplified mathematical model for insonation of a static, lossless, statistically homogeneous, weakly scattering medium. Specifically, the autocovariance function for received power is derived, which functionally is the square of the (deterministic) autocorrelation function of the effective sample volumes produced by the transducer pair for varying frequencies, at least if a delta correlated medium is assumed. A marginal broadening of the modeled autocovariance functions is expected for insonation of blood. The theory is applicable to any transducer aperture, but has been experimentally verified here with 5-MHz, 6.35-mm circular transducers using an agar phantom containing small, randomly dispersed glass particles. A similar experimental verification of a transducer used in multiple-frequency blood perfusion measurements shows that the model proposed in this paper is plausible for explaining the decorrelation between different channels in such a measurement.}},
  author       = {{Jansson, Tomas and Jurkonis, Rytis and Mast, T Douglas and Persson, Hans W and Lindström, Kjell}},
  issn         = {{0885-3010}},
  keywords     = {{Rheology; Regional Blood Flow : physiology; Imaging; Phantoms; Structural; Models; Cardiovascular; Artifacts; Blood Flow Velocity; Support; Non-U.S. Gov't; Ultrasonography : methods}},
  language     = {{eng}},
  number       = {{6}},
  pages        = {{715--725}},
  publisher    = {{IEEE - Institute of Electrical and Electronics Engineers Inc.}},
  series       = {{IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control}},
  title        = {{Frequency dependence of speckle in continuous-wave ultrasound with implications for blood perfusion measurements.}},
  url          = {{https://lup.lub.lu.se/search/files/2632359/623629.pdf}},
  doi          = {{10.1109/TUFFC.2002.1009330}},
  volume       = {{49}},
  year         = {{2002}},
}