Experimentally obtained estimates of threedimensional (3D) velocity vectors using the 3D Transverse Oscillation (TO) method are presented. The method employs a 2D transducer and synthesizes two double-oscillating fields in receive to obtain the axial, transverse, and elevation velocity components simultaneously. Experimental data are acquired using the ultrasound research scanner SARUS. The double-oscillating TO fields are investigated in an experimental scanning tank setup. The results demonstrate that the created fields only oscillate in the axial plus either the transverse or the elevation direction. Velocity measurements are conducted in an experimental flow-rig with steady flow in two different directions (mainly in x or y direction). Velocity estimates are obtained along the z axis. All three velocity components (vx, vy, vz) are measured with relative biases and standard deviations (normalized to expected value) below 5% and 12%, respectively. For an expected velocity magnitude of 25.2 cm/s, the method estimates 24.4±3.1 cm/s and 25.1±1.9 cm/s for the two directions. Under similar conditions, Field II simulations yield 25.1±1.5 cm/s and 25.4±1.6 cm/s. The experimental results validate the results obtained through simulations and verify that the 3D TO method estimates the full 3D velocity vectors simultaneously as well as the correct velocity magnitudes.
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机译:提出了使用3D横向振荡(TO)方法对三维(3D)速度矢量进行实验获得的估计值。该方法采用2D换能器,并合成接收中的两个双振荡场,以同时获得轴向,横向和仰角速度分量。使用超声研究扫描仪SARUS获取实验数据。在实验扫描槽设置中研究了双振荡TO场。结果表明,所创建的场仅在轴向,横向或仰角方向上振荡。速度测量是在实验流动平台上进行的,流体在两个不同方向(主要在x或y方向)上保持稳定流动。沿z轴获得速度估算值。测量所有三个速度分量(vx,vy,vz)时的相对偏差和标准偏差(标准化为期望值)分别低于5%和12%。对于25.2 cm / s的预期速度幅值,该方法在两个方向上估计为24.4±3.1 cm / s和25.1±1.9 cm / s。在相似的条件下,Field II模拟得出25.1±1.5 cm / s和25.4±1.6 cm / s。实验结果验证了通过仿真获得的结果,并验证了3D TO方法可同时估计完整的3D速度矢量以及正确的速度幅值。
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