论文信息 - Accuracy assessment of a Lucas-Kanade based correlation method for 3D PIV

Accuracy assessment of a Lucas-Kanade based correlation method for 3D PIV

We introduce and characterize a new 3D cross-correlation algorithm, which relies on gradient-based iterative volume deformation. The algorithm, FOLKI3D, is the extension to 3D PIV of the approach introduced by Champagnat et al. 2011. It has a highly parallel structure and is implemented on GPU. Additionally to the gradient approach for displacement estimation, we implemented a high-order interpolation scheme (with cubic B-Splines) in the volume deformation step, at a reasonable computational cost. Performance tests on synthetic volumic distributions first allow to characterize the spatial transfer function of the algorithm, and to confirm the efficiency of this interpolator, comparable to that of standard image deformation methods in planar PIV. A second series of synthetic tests then investigates the response of FOLKI3D to sources of noise specific to the tomographic PIV context, i.e. ghost particles. Depending on the tests, the algorithm is found as efficient or more robust than the state-of-the-art. The gain brought by the high-order interpolation is also confirmed in a situation with a large number of ghosts, and different reconstructed particle shapes.

[1] Michel Stanislas,et al. Main results of the third international PIV Challenge , 2008 .

[2] F. Champagnat,et al. Fast and accurate PIV computation using highly parallel iterative correlation maximization , 2011 .

[3] Tommaso Astarita,et al. Analysis of interpolation schemes for image deformation methods in PIV , 2005 .

[4] Frédéric Champagnat,et al. Computationally efficient sparse algorithms for tomographic PIV Reconstruction , 2013 .

[5] Fulvio Scarano,et al. Advances in iterative multigrid PIV image processing , 2000 .

[6] Frédéric Champagnat,et al. Efficient Cubic B-spline Image Interpolation on a GPU , 2012, J. Graph. Tools.

[7] Simon Baker,et al. Lucas-Kanade 20 Years On: A Unifying Framework , 2004, International Journal of Computer Vision.

[8] J. Westerweel,et al. Universal outlier detection for PIV data , 2005 .

[9] Ferry Schrijer,et al. Effect of predictor–corrector filtering on the stability and spatial resolution of iterative PIV interrogation , 2008 .

[10] Fulvio Scarano,et al. On the velocity of ghost particles and the bias errors in Tomographic-PIV , 2011 .

[11] Fulvio Scarano,et al. Tomographic PIV: principles and practice , 2012 .

[12] Julio Soria,et al. An efficient simultaneous reconstruction technique for tomographic particle image velocimetry , 2009 .

[13] Bernhard Wieneke,et al. Tomographic particle image velocimetry , 2006 .