Vector flow imaging(VFI)is an innovative ultrasound flow measurement technology.Compared with the traditional color Doppler and spectral Doppler,VFI has the advantages of independence of angle correction and direct acquisition of real-time amplitude and direction of flow.Transverse oscillation(TO)method is one of the effective methods for vector flow imaging.However,a complete and detailed algorithm validation process based on commercial ultrasound machines is still lacking due to more complex convex probes.This study starts with introducing the imaging process and principle of transverse oscillation vector flow technique,and calculates the error between the set velocity value and the measured velocity value through the simulation experiment,and verifies the error between the set velocity value and the measured velocity value through the Doppler flow phantom experiment.Among them,the velocity value measured by the TO vector flow technique in the simulation experiment is 0.48 m/s and the preset value is 0.50 m/s,the error between them is-4％.The velocity values are 8.33,11.14,14.44 and 16.67 cm/s measured by the Doppler flow phantom experiment,the actual velocity values are 7.97,10.78,14.06 and 17.34 cm/s,the errors between them are all within±5％.Both experiments verify the feasibility of using vector flow technique on abdominal convex probe.

The paper described the hemodynamics of blood flow based on fluid mechanics and its corresponding formulas, and revealed the limitation of blood flow velocity measurement for non-laminar flow when using the conventional pulse wave Doppler. The paper demonstrated the calculation of turbulence for blood flow based on velocity directions and quantified the turbulence according to the presented formulas. Two methods were introduced and the simulated results were analyzed. An example using real data based on ultrasound vector flow imaging for calculating the turbulence of blood flow was presented in the end.
Blood Flow Velocity ; Ultrasonography

Echocardiogram is vital for the diagnosis of cardiac disease. The heart has complex hemodynamics requiring an advanced ultrasound imaging mode. Cardiac ultrasound vector flow imaging is capable of measuring the actual magnitude and direction of the blood flow velocity, obtaining the quantitative parameters of hemodynamics, and then providing more information for clinical research and diagnosis. This study mainly reviewed several different vector flow imaging techniques for cardiac flow and presented the implementation difficulties, and proposed a diverging wave based high frame rate cardiac ultrasound vector flow imaging. The study discussed the limitation of current ultrasound technology used in the cardiac flow measurement, analyzed and demonstrated the specific reasons for these implementation difficulties and the potential future development.
Blood Flow Velocity ; Heart/physiology* ; Hemodynamics ; Ultrasonography