A comparison of flow tracking techniques: spatial quadrature with phase-sensitive axial demodulation versus speckle tracking
- Resource Type
- Conference
- Authors
- Anderson, M.E.; Bohs, L.N.; Gebhart, S.C.
- Source
- 1999 IEEE Ultrasonics Symposium. Proceedings. International Symposium (Cat. No.99CH37027) Ultrasonics Ultrasonics Symposium, 1999. Proceedings. 1999 IEEE. 2:1471-1475 vol.2 1999
- Subject
- Signal Processing and Analysis
Fields, Waves and Electromagnetics
Components, Circuits, Devices and Systems
Engineered Materials, Dielectrics and Plasmas
Demodulation
Speckle
Tracking
Motion estimation
Scattering
Phase estimation
Spatial resolution
Computational geometry
Data flow computing
Imaging phantoms
- Language
- ISSN
- 1051-0117
Spatial quadrature and speckle tracking are both techniques which extend the estimation of flow velocity or tissue motion velocity to two or three dimensions. The authors applied both under similar experimental conditions to assess and compare their performance. They also describe a new spatial quadrature processor that obviates the need for axial alignment under conditions of mixed axial-lateral flow. This processor avoids the estimate bias produced by jitter in the axial alignment step previously described, and thus allows the non-axial component(s) of flow to be tracked without sacrificing axial resolution. In the authors' flow experiment, summed radiofrequency echo data were captured in an M-mode scan geometry using 2:1 parallel receive processing in both spatial quadrature and two-beam speckle tracking configurations using a 7.5 MHz linear array and a modified commercial ultrasound scanner. Laminar flow was established in a wall-less vessel phantom using a computer-controlled pump. The authors captured echo data from this phantom at beam-vessel angles of 60/spl deg/ and 90/spl deg/ (i.e. pure lateral flow). These data were processed off-line to estimate flow velocity profiles. Volume flow rates were calculated from these profiles by integration. The mean volume flow rates estimated with 2-D speckle tracking agreed with the known flow rates with a maximum relative error of 7% for true lateral flow and 10% for mixed axial-lateral flow. The equivalent values for spatial quadrature were 5% and 15%.