A Framework for Fluid Motion Estimation using a Constraint-Based Refinement Approach
November 24, 2020 Β· Declared Dead Β· π Machine Graphics and Vision: international journal
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Authors
Hirak Doshi, N. Uday Kiran
arXiv ID
2011.12267
Category
cs.CV: Computer Vision
Cross-listed
math.AP
Citations
1
Venue
Machine Graphics and Vision: international journal
Last Checked
4 months ago
Abstract
Physics-based optical flow models have been successful in capturing the deformities in fluid motion arising from digital imagery. However, a common theoretical framework analyzing several physics-based models is missing. In this regard, we formulate a general framework for fluid motion estimation using a constraint-based refinement approach. We demonstrate that for a particular choice of constraint, our results closely approximate the classical continuity equation-based method for fluid flow. This closeness is theoretically justified by augmented Lagrangian method in a novel way. The convergence of Uzawa iterates is shown using a modified bounded constraint algorithm. The mathematical wellposedness is studied in a Hilbert space setting. Further, we observe a surprising connection to the Cauchy-Riemann operator that diagonalizes the system leading to a diffusive phenomenon involving the divergence and the curl of the flow. Several numerical experiments are performed and the results are shown on different datasets. Additionally, we demonstrate that a flow-driven refinement process involving the curl of the flow outperforms the classical physics-based optical flow method without any additional assumptions on the image data.
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