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A Duality Based Approach for Realtime TV-L 1 Optical Flow

A Duality Based Approach for Realtime TV-L 1 Optical Flow. Christopher Zach 1 , Thomas Pock 2 , and Horst Bischof 2. 1 VRVis Research Center, Graz 2 Institute for Computer Graphics and Vision, TU Graz E-mail: { zach, pock, bischof }@icg.tugraz.at. time. Motivation.

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A Duality Based Approach for Realtime TV-L 1 Optical Flow

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  1. A Duality Based Approach for Realtime TV-L1 Optical Flow Christopher Zach1, Thomas Pock2, and Horst Bischof2 1 VRVis Research Center, Graz 2 Institute for Computer Graphics and Vision, TU Graz E-mail: {zach, pock, bischof}@icg.tugraz.at

  2. time Motivation • Discontinuity preserving regularization of the flow field • Robustness to occulsions • Handle large displacements • Realtime (> 30 fps) for large images (512x512)

  3. Outline • (I) Variational Optical Flow • (II) TV-L1 optical flow • (III) Duality Based Approach • (IV) Acceleration using the GPU • (V) Performance Evaluation • (VI) Conclusion & Demo

  4. Optical Flow • Optical Flow (OF) is a major task of biological and artificial visual systems • Relates the motion of pixel intensities between consecutive image frames • Optical Flow Constraint: • Gives only the normal flow • No OFC in untextured areas u1 u2 u

  5. Variational Optical Flow • First studied by Horn and Schunck in 1981 [1] • Quadratic regularization does not allow for discontinuities and occlusions • Modifying the Horn and Schunck functional was pioneered by Black and Rangarajan [2] [1] B.K. Horn and B.G. Schunck. Determinig Optical Flow. Artificial Intelligence, 1981 [2] M.J. Black and P. Rangarajan. On the Unification of Line Processes, Outlier Rejection and Robust Statistics with Applications in Early Vision, IJCV, 1996

  6. TV-L1 Optical Flow • We use a robust variant of the Horn-Schunck formulation • Total Variation (TV) of Rudin Osher and Fatemi (ROF) [3] • L1 penalization of the OF constraint • TV-L1 has been used in many approaches • Allows for discontinuities in the flow field and outliers in the optical flow constraint • Sophisticated optimization techniques are needed • This is the major goal of this paper [3] L. Rudin and S. Osher and E. Fatemi. Nonlinear Total Variation Based Noise Removal Algorithms, Physica D, 1992

  7. Eθ E as Θ 0 An Approximative Formulation • Main difficulty is induced by the TV term –> ROF model [3] • Simple pointwise optimization problem -> Thresholding [3] L. Rudin and S. Osher and E. Fatemi. Nonlinear Total Variation Based Noise Removal Algorithms, Physica D, 1992

  8. Primal Formulation • Study of the ROF model • Primal Euler Lagrange equations • Degenerated if gradient vanishes • Simple solution: Replace by • Disadvantage: Large εsmoothes edges!

  9. |p| ≤ 1 p Dual Formulation • Studied by Chan [4], and later by Chambolle [5] • One arrives at two new equations • Dual Euler Lagrange Equations • Advantage: No regularization is needed! [4] T. Chan and G. Golub and P. Mulet, A Nonlinear Primal Dual Method for TV-based Image Restoration, 1999 [5] A. Chambolle, An Algorithm for Total Variation Minimization and Applications, 2004

  10. Primal vs. Dual • Convergence of the Primal and Dual formulation • Primal: fixed-point scheme of Vogel & Oman [6] • Dual: fixed-point scheme of Chambolle [5] ε=10 ε=10-15 ε=10-1 ε=1 EROF iterations [5] A. Chambolle, An Algorithm for Total Variation Minimization and Applications, 2004 [6] C. R. Vogel and M. E. Oman. Iterative Methods For Total Variation Denoising. 1996

  11. Final Algorithm • Energy minimization is embedded into a coarse-to-fine approach to handle large displacements • Solved via alternating optimization • Fix v, minimize wrt. u (Chambolle‘s algorithm) • Fix u, minimize wrt. v (Thresholding) • Goto 1 until convergence

  12. G92 Nov 2007 Implementation on Graphics Hardware • Particularly well suited to compute variational methods • High degree of parallelism • High performance processing units • All features can be accessed via C-like languages • Performance of graphics cards is steadily increasing

  13. Performance Evaluation Frames per second Error evaluation on the well known Yosemite without clouds sequence [1] B.K. Horn and B.G. Schunck. Determinig Optical Flow. Artificial Intelligence, 1981 [7] T. Nir and A.M. Bruckstein and R. Kimmel, Over-Parameterized Variational Optical Flow, IJCV 2007

  14. Conclusion & Future work • We have developed a duality based algorithm for TV-L1 optical flow computation • We have implemented this algorithm on state-of-the-art graphics hardware • In summary, we obtained an optical flow algorithm having a realtime performance of ~45 fps for 512x512 images • Implementation in CUDA should give an additional speedup • More sophisticated data terms for illumination changes • Multigrid techniques for the dual formulation

  15. Demo

  16. Solution of the ROF model • Compute the minimizer of ROF model • Solution of a huge sytem of non-linear equations • Leads to iterative algorithms • Primal formulation: • Fixed-point scheme of Vogel and Oman [6] • Dual formulation • Fixed-point scheme of Chambolle [5] [5] A. Chambolle, An Algorithm for Total Variation Minimization and Applications, 2004 [6] C. R. Vogel and M. E. Oman. Iterative Methods For Total Variation Denoising. 1996

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