Lagrangian interpolation algorithm for PIV data

•A method for estimating velocity field data within masked regions of PIV data is developed.•When applied toexperimental data, up to a 5× improvement on average velocity reconstruction error is observedin comparison to bi-linear interpolation.•Application to the estimation of body forces using contr...

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Bibliographic Details
Published in:The International journal of heat and fluid flow 2020-12, Vol.86, p.108733, Article 108733
Main Authors: Vocke, Maegan, Bingham, Conrad, Riches, Graham, Martinuzzi, Robert, Morton, Chris
Format: Article
Language:English
Subjects:
Interpolation
Lagrangian
Masking
Particle image velocimetry
Vortex impulse
Vortex shedding
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Summary:•A method for estimating velocity field data within masked regions of PIV data is developed.•When applied toexperimental data, up to a 5× improvement on average velocity reconstruction error is observedin comparison to bi-linear interpolation.•Application to the estimation of body forces using control volume theory is provided.•Results show up to 10× improvement in the estimation of volume integral contributions to instantaneous drag and lift. A new Lagrangian based interpolation scheme is proposed for recovering velocity field data from within masked regions in particle image velocimetry (PIV) experiments. As a first step, the mean field within the masked region is filled through an iterative convolution operation using an optimized kernel. Next, the Lagrangian interpolation scheme estimates velocity field data within the masked region using a weighted average of past and future snapshot data along a mean field streamline from outside of the masked region. The Lagrangian interpolation scheme is compared directly with a traditional bilinear interpolation approach for two datasets: the flow development over a circular cylinder within the laminar vortex shedding regime (ReD=150) and turbulent vortex shedding regime (ReD=3000). The results show that for both Reynolds numbers investigated, the Lagrangian approach provides up to a 5× improvement in average velocity reconstruction error. Application of the proposed interpolation scheme to the estimation of body forces was assessed. For both the momentum and impulse control volume approaches to estimate instantaneous forces, the Lagrangian interpolation scheme provides up to 10× improvement in the estimation of volume integral contributions to instantaneous drag and lift.
ISSN:0142-727X
1879-2278
DOI:10.1016/j.ijheatfluidflow.2020.108733