DocumentCode
1467863
Title
Doppler angle and flow velocity estimations using the classic and transverse Doppler effects
Author
Lee, Bor-Ray ; Chiang, Huihua Kenny ; Kuo, Cheng-Deng ; Lin, Win-Li ; Lee, San-Kan
Author_Institution
Inst. of Biomed. Eng., Nat. Yang-Min Univ., Taipei, Taiwan
Volume
46
Issue
1
fYear
1999
Firstpage
252
Lastpage
256
Abstract
Current clinical Doppler ultrasound systems could only measure the flow vector parallel to the ultrasound beam axis, and the knowledge of the Doppler angle (beam-to-flow angle) is needed to calculate the real flow velocity. Currently, the Doppler angle is determined visually by manually aligning a vessel axis marker along the blood vessel on the duplex scan image of the ultrasound. The application of this procedure is often limited by practical constraints; therefore, measurements are not reliable. In order to overcome this problem, the authors developed a simple Doppler angle and flow velocity estimation method using a combination of the classic and transverse Doppler effects. This method uses only a single focused annular array transducer to estimate the Doppler angle and the flow velocity. The authors have verified experimentally that this method is successful for measuring constant flow in a flow phantom between 45/spl deg/ and 80/spl deg/ Doppler angle. The standard deviation of the estimated Doppler angles is less than 4.5/spl deg/. This method could be implemented easily in medical Doppler ultrasound systems to automatically estimate the Doppler angle and the flow velocity.
Keywords
Doppler measurement; biomedical ultrasonics; blood flow measurement; ultrasonic velocity measurement; Doppler angle; beam-to-flow angle; blood vessel; classic Doppler effects; clinical Doppler ultrasound systems; duplex scan image; flow phantom; real flow velocity calculation; single focused annular array transducer; transverse Doppler effects; unreliable measurements; vessel axis marker alignment; Biomedical imaging; Blood vessels; Current measurement; Doppler effect; Fluid flow measurement; Focusing; Transducers; Ultrasonic imaging; Ultrasonic variables measurement; Velocity measurement;
fLanguage
English
Journal_Title
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
Publisher
ieee
ISSN
0885-3010
Type
jour
DOI
10.1109/58.741545
Filename
741545
Link To Document