Convex array vector velocity imaging using transverse oscillation and its optimization
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Convex array vector velocity imaging using transverse oscillation and its optimization. / Jensen, Jorgen Arendt; Brandt, Andreas Hjelm; Nielsen, Michael Bachmann.
In: IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, Vol. 62, No. 12, 734897, 12.2015, p. 2043-2053.Research output: Contribution to journal › Journal article › Research › peer-review
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TY - JOUR
T1 - Convex array vector velocity imaging using transverse oscillation and its optimization
AU - Jensen, Jorgen Arendt
AU - Brandt, Andreas Hjelm
AU - Nielsen, Michael Bachmann
N1 - Publisher Copyright: © 1986-2012 IEEE.
PY - 2015/12
Y1 - 2015/12
N2 - A method for obtaining vector flow images using the transverse oscillation (TO) approach on a convex array is presented. The paper presents optimization schemes for TO fields and evaluates their performance using simulations and measurements with an experimental scanner. A 3-MHz 192-element convex array probe (pitch 0.33 mm) is used in both simulations and measurements. A parabolic velocity profile is simulated at a beam-to-flow angle of 90°. The optimization routine changes the lateral oscillation period λ as a function of depth to yield the best possible estimates based on the energy ratio between positive and negative spatial frequencies in the ultrasound field. The energy ratio is reduced from -17.1 dB to -22.1 dB. Parabolic profiles are estimated on simulated data using 16 emissions. The optimization gives a reduction in standard deviation from 8.81% to 7.4% for 16 emissions, with a reduction in lateral velocity bias from -15.93% to 0.78% at 90° (transverse flow) at a depth of 40 mm. Measurements have been performed using the experimental ultrasound scanner and a convex array transducer. A bias of -0.93% was obtained at 87° for a parabolic velocity profile along with a standard deviation of 6.37%. The livers of two healthy volunteers were scanned using the experimental setup. The in vivo images demonstrate that the method yields realistic estimates with a consistent angle and mean velocity across three heart cycles.
AB - A method for obtaining vector flow images using the transverse oscillation (TO) approach on a convex array is presented. The paper presents optimization schemes for TO fields and evaluates their performance using simulations and measurements with an experimental scanner. A 3-MHz 192-element convex array probe (pitch 0.33 mm) is used in both simulations and measurements. A parabolic velocity profile is simulated at a beam-to-flow angle of 90°. The optimization routine changes the lateral oscillation period λ as a function of depth to yield the best possible estimates based on the energy ratio between positive and negative spatial frequencies in the ultrasound field. The energy ratio is reduced from -17.1 dB to -22.1 dB. Parabolic profiles are estimated on simulated data using 16 emissions. The optimization gives a reduction in standard deviation from 8.81% to 7.4% for 16 emissions, with a reduction in lateral velocity bias from -15.93% to 0.78% at 90° (transverse flow) at a depth of 40 mm. Measurements have been performed using the experimental ultrasound scanner and a convex array transducer. A bias of -0.93% was obtained at 87° for a parabolic velocity profile along with a standard deviation of 6.37%. The livers of two healthy volunteers were scanned using the experimental setup. The in vivo images demonstrate that the method yields realistic estimates with a consistent angle and mean velocity across three heart cycles.
KW - Arrays
KW - Focusing
KW - Frequency measurement
KW - Optimization
KW - Oscillators
KW - Transducers
UR - http://www.scopus.com/inward/record.url?scp=84961642223&partnerID=8YFLogxK
U2 - 10.1109/TUFFC.2015.006970
DO - 10.1109/TUFFC.2015.006970
M3 - Journal article
AN - SCOPUS:84961642223
VL - 62
SP - 2043
EP - 2053
JO - I E E E Transactions on Ultrasonics, Ferroelectrics and Frequency Control
JF - I E E E Transactions on Ultrasonics, Ferroelectrics and Frequency Control
SN - 0885-3010
IS - 12
M1 - 734897
ER -
ID: 331500102