Litcius/Paper detail

Holographic astigmatic particle tracking velocimetry (HAPTV)

Zhou Zhou, Santosh Kumar S, Kevin Mallery, Wensheng Jiang, Jiarong Hong

2020Measurement Science and Technology15 citationsDOIOpen Access PDF

Abstract

Abstract The formation of twin images in digital inline holography (DIH) prevents the placement of the focal plane in the center of a sample volume for DIH-based particle tracking velocimetry (DIH-PTV) with a single camera. As a result, it is challenging to apply DIH-PTV for flow measurements in large-scale laboratory facilities or many field applications where it would otherwise be desirable due to the low cost and compact setup. Here we introduce holographic astigmatic PTV (HAPTV) by inserting a cylindrical lens in the optical setup of DIH-PTV, generating distorted holograms. Such distortion is subsequently utilized in a customized reconstruction algorithm to distinguish tracers positioned on different sides of the focal plane which can in turn be placed in the middle of a sample volume. Our HAPTV approach is calibrated under high (1 µm pixel −1 ) and low (10 µm pixel −1 ) magnifications with an error standard deviation of 4.2 µm (one particle diameter) and 120.7 µm (~5 times the particle diameter), respectively. We compare the velocity field of a laminar jet flow obtained using HAPTV and conventional PIV to illustrate the accuracy of the technique when applied to practical flow measurement applications. The work demonstrates that HAPTV improves upon the depth of field of conventional astigmatic PTV and enables the implementation of DIH-based PTV for in situ applications.

Topics & Concepts

Particle tracking velocimetryOpticsCardinal pointHolographyTracking (education)PhysicsDistortion (music)Laminar flowVelocimetryPlane (geometry)Lens (geology)Digital holographyDepth of fieldParticle image velocimetryParticle (ecology)Sample (material)Flow (mathematics)PixelImage planeCylindrical lensStandard deviationFocal lengthField (mathematics)Flow measurementField of viewAccuracy and precisionVolume (thermodynamics)Digital Holography and MicroscopyFluid Dynamics and Turbulent FlowsFlow Measurement and Analysis