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Abstract

A computational model has been developed to observe the effects of several instrumental parameters and systematic error sources on ultrasonic volumetric flow measurements in vessels using an error compensation method proposed previously by the authors. The effects of two essential instrumental parameters, the gate length and pulse duration, on two intermediate flow results and an optimal correction factor as a function of the beam width-to-vessel diameter ratio (BWR) have been studied under steady flow conditions. The corrected flow results under typical combinations of those parameters show that by proper selection of a correction factor, the proposed method can compensate for those systematic errors. If the estimated BWR is within ±0.1 of the actual BWR value, the systematic error can be limited to within 6.5%. The study also shows that the compensation method can effectively reduce the errors caused by other systematic error sources such as the system sensitivity and high-pass filter function, as well as misalignment of the ultrasound beam from the center of the vessel.

Keywords

Beam width-to-vessel diameter ratio correction theory ultrasound volumetric flow

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References

Baker

D. W.

Forster

F. K.

Daigle

R. E.

, Doppler principles and techniques, in Ultrasound: Its applications In Medicine and Biology. Part 1. Methods and Phenomena 3, Fry

F. J.

, Ed., pp. 219–254; (Elsevier Science, Inc., Amsterdam, 1978).

Evans

D. H.

, Some aspects of the relationship between instantaneous volumetric blood flow and continuous wave Doppler ultrasound recordings-I, Ultrasound Med. Biol. 8, 605–609 (1982).

Evans

D. H.

, On the measurement of the mean velocity of blood flow over the cardiac cycle using Doppler ultrasound, Ultrasound Med. Biol. 11, 735–741 (1985).

Gill

R. W.

, Accuracy calculations for ultrasonic pulsed Doppler blood flow measurements, Australasian Phys. Eng. Sci. Med. 5, 51–57 (1982).

Gill

R. W.

, Measurement of blood flow by ultrasound: accuracy and sources of error, Ultrasound Med. Biol. 11, 625–641 (1985).

Oates

C. P.

Williams

E. D.

McHugh

M. I.

, The use of a Diasonics DRF400 duplex ultrasound scanner to measure volume flow in arterio-venous fistulae in patients undergoing hemodialysis: an analysis of measurement uncertainties, Ultrasound Med. Biol. 16, 571–579 (1990).

Fei

D. Y.

, A theory to correct the systematic error caused by the imperfectly matched beam width to vessel diameter ratio on volumetric flow measurements using ultrasound techniques, Ultrasound Med. Biol. 21, 1047–1057 (1995).

Willink

R. D.

Evens

D. H.

, A mean blood velocity statistic for the Doppler signal from a narrow ultrasound beam, IEEE Trans. Biomed. Eng. 41, 322–331 (1994).

Willink

R. D.

Evens

D. H.

, Volumetric blood flow calculation using a narrow ultrasound beam, Ultrasound Med. Biol. 21, 203–216 (1995).

10.

Willink

R. D.

, Mean blood velocity measurement with a narrow ultrasound beam and an asymmetric velocity profile, IEEE Trans. Biomed. Eng. 46, 362–364 (1999).

11.

Fei

D. Y.

C. T.

Brewer

W. H.

Kraft

K. A.

, Angle independent Doppler color imaging: determination of accuracy and a method of display, Ultrasound Med. Biol. 20, 147–155 (1994).

12.

Fei

D. Y.

Liu

D. D.

C. T.

Makhoul

R. G.

Fisher

R. M.

, Feasibility of angle independent Doppler color imaging for in vivo application: Preliminary study on carotid arteries, Ultrasound Med. Biol. 22, 56–67 (1997).

13.

Picot

P. A.

Embree

P. M.

, Quantitative volume flow estimation using velocity profiles, IEEE Trans. Ultron. Ferroele. Ferq. Contr. 41, 340–345 (1994).

Ultrasonic Error Compensation Method to Correct Instrumental and Systematic Errors in Volumetric Flow Measurements: A Theoretical Study

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