Results and Rankings

Results for methods appear here after users upload them and approve them for public display.



EPE all EPE matched EPE unmatched d0-10 d10-60 d60-140 s0-10 s10-40 s40+
GroundTruth [1] 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 Visualize Results
FTFlow [2] 5.390 2.268 30.841 4.513 1.964 1.366 1.046 3.322 31.936 Visualize Results
DCFlow [3] 5.119 2.283 28.228 4.665 2.108 1.440 1.052 3.434 29.351 Visualize Results
FlowFieldsCNN [4] 5.363 2.303 30.313 4.718 2.020 1.399 1.032 3.065 32.422 Visualize Results
InterpoNet_ff [5] 5.535 2.372 31.296 4.720 2.018 1.532 1.064 3.496 32.633 Visualize Results
PWC-Net [6] 5.042 2.445 26.221 4.636 2.087 1.475 0.799 2.986 31.070 Visualize Results
ProbFlowFields [7] 5.696 2.545 31.371 4.696 2.150 1.686 1.146 3.658 33.188 Visualize Results
S2F-IF [8] 5.417 2.549 28.795 4.745 2.198 1.712 1.157 3.468 31.262 Visualize Results
SegFlow [9] 5.665 2.558 30.981 4.594 2.118 1.653 1.052 3.331 34.174 Visualize Results
AutoScaler+ [10] 6.076 2.569 34.656 4.610 2.195 1.863 1.298 3.737 35.431 Visualize Results
InterpoNet_cpm [11] 5.627 2.594 30.344 4.975 2.213 1.640 1.042 3.575 33.321 Visualize Results
FlowFields [12] 5.810 2.621 31.799 4.851 2.232 1.682 1.157 3.739 33.890 Visualize Results
DeepDiscreteFlow [13] 5.728 2.623 31.042 5.347 2.478 1.590 0.959 3.072 35.819 Visualize Results
InterpoNet_dm [14] 5.711 2.650 30.642 5.078 2.308 1.762 0.997 3.702 33.929 Visualize Results
PGM-C [15] 5.591 2.672 29.389 4.975 2.340 1.791 1.057 3.421 33.339 Visualize Results
FlowFields+ [16] 5.707 2.684 30.356 4.691 2.117 1.793 1.131 3.330 34.167 Visualize Results
CPM_AUG [17] 5.645 2.737 29.362 4.707 2.150 1.918 1.087 3.306 33.925 Visualize Results
FlowNet2-ft-sintel [18] 5.739 2.752 30.108 4.818 2.557 1.735 0.959 3.228 35.538 Visualize Results
SPM-BPv2 [19] 5.812 2.754 30.743 4.736 2.255 1.933 1.048 3.468 35.118 Visualize Results
RicFlow [20] 5.620 2.765 28.907 5.146 2.366 1.679 1.088 3.364 33.573 Visualize Results
InterpoNet_df [21] 6.044 2.788 32.581 5.154 2.404 1.779 0.985 3.377 37.596 Visualize Results
MR-Flow [22] 5.376 2.818 26.235 5.109 2.395 1.755 0.908 3.443 32.221 Visualize Results
FullFlow [23] 5.895 2.838 30.793 4.905 2.506 1.913 1.136 3.373 35.592 Visualize Results
DiscreteFlow+OIR [24] 5.862 2.864 30.303 5.153 2.427 1.825 1.118 3.698 34.633 Visualize Results
DiscreteFlow [25] 6.077 2.937 31.685 5.106 2.459 1.945 1.074 3.832 36.339 Visualize Results
GlobalPatchCollider [26] 6.040 2.938 31.309 5.310 2.624 1.824 1.102 3.589 36.455 Visualize Results
NNF-Local [27] 7.249 2.973 42.088 4.896 2.817 2.218 1.159 4.183 44.866 Visualize Results
FlowNet2 [28] 6.016 2.977 30.807 5.139 2.786 2.102 1.243 4.027 34.505 Visualize Results
CPM-Flow [29] 5.960 2.990 30.177 5.038 2.419 2.143 1.155 3.755 35.136 Visualize Results
Deep+R [30] 6.769 2.996 37.494 5.182 2.770 2.064 1.157 3.837 41.687 Visualize Results
CPM2 [31] 6.180 3.012 32.008 5.059 2.399 2.126 1.212 3.625 37.014 Visualize Results
EpicFlow [32] 6.285 3.060 32.564 5.205 2.611 2.216 1.135 3.727 38.021 Visualize Results
DeepFlow2 [33] 6.928 3.093 38.166 5.207 2.819 2.144 1.182 3.859 42.854 Visualize Results
F3-MPLF [34] 6.274 3.093 32.210 5.045 2.859 2.082 1.083 3.227 39.409 Visualize Results
FGI [35] 6.607 3.101 35.158 5.432 2.970 2.131 1.152 3.986 39.985 Visualize Results
EPMNet [36] 6.134 3.141 30.540 5.431 2.987 2.152 1.306 4.188 34.780 Visualize Results
PatchBatch+Inter [37] 6.222 3.167 31.122 5.246 2.862 2.152 0.905 3.200 39.912 Visualize Results
MirrorFlow [38] 6.071 3.186 29.567 5.433 2.801 1.943 0.930 3.183 38.544 Visualize Results
SparseFlowFused [39] 7.189 3.286 38.977 5.567 3.098 2.159 1.275 3.963 44.319 Visualize Results
DeepFlow [40] 7.212 3.336 38.781 5.650 3.144 2.208 1.284 4.107 44.118 Visualize Results
TF+OFM [41] 6.727 3.388 33.929 5.544 3.238 2.551 1.512 3.765 39.761 Visualize Results
PPM [42] 7.177 3.392 38.025 5.212 2.771 2.642 1.155 3.790 45.233 Visualize Results
SPM-BP [43] 7.325 3.493 38.561 5.534 3.052 2.691 1.279 4.385 44.434 Visualize Results
PatchBatch-CENT+SD [44] 6.783 3.507 33.498 6.080 3.408 2.103 0.725 3.064 45.858 Visualize Results
FALDOI [45] 7.337 3.580 37.904 5.332 3.434 2.885 1.487 4.355 43.526 Visualize Results
ZZZ [46] 8.103 3.604 44.772 5.529 3.212 2.925 1.641 4.832 48.068 Visualize Results
PMF [47] 7.630 3.607 40.435 5.584 3.171 2.770 1.266 4.414 46.985 Visualize Results
M-1px [48] 8.229 3.680 45.306 5.654 3.267 2.997 1.718 5.023 48.284 Visualize Results
AggregFlow [49] 7.329 3.696 36.929 5.538 3.435 2.918 1.241 4.296 44.858 Visualize Results
BOOM+PF.XY [50] 7.600 3.731 39.137 5.766 3.599 2.798 1.488 4.709 44.902 Visualize Results
S2D-Matching [51] 6.817 3.737 31.920 5.954 3.380 2.544 1.157 3.831 42.097 Visualize Results
FlowNetS+ft+v [52] 7.218 3.752 35.445 6.439 3.635 2.292 1.358 4.609 42.571 Visualize Results
PatchWMF-OF [53] 7.971 3.766 42.218 5.712 3.568 2.797 1.279 4.970 48.396 Visualize Results
ICALD [54] 7.554 3.784 38.270 6.065 3.812 2.626 1.336 4.939 44.705 Visualize Results
PH-Flow [55] 7.423 3.795 36.960 5.550 3.675 2.716 1.119 4.827 44.926 Visualize Results
BOOM+PF.XYT [56] 7.683 3.828 39.117 5.797 3.694 2.902 1.585 4.794 44.921 Visualize Results
WLIF-Flow [57] 8.049 3.837 42.348 5.851 3.657 2.811 1.290 5.033 48.843 Visualize Results
SparseFlow [58] 7.851 3.855 40.401 6.117 3.838 2.557 1.071 3.771 51.353 Visualize Results
SVFilterOh [59] 7.737 3.920 38.851 5.954 3.499 3.160 1.403 4.731 46.420 Visualize Results
AnyFlow [60] 7.933 3.994 40.027 6.284 3.997 2.756 2.279 5.391 42.122 Visualize Results
ContFusion [61] 7.857 4.010 39.194 6.265 4.022 2.797 1.333 4.981 47.158 Visualize Results
LocalLayering [62] 8.043 4.014 40.879 5.680 3.841 3.122 1.186 4.990 49.426 Visualize Results
FlowNetC+ft+v [63] 7.883 4.132 38.426 6.466 3.952 2.860 1.369 5.049 47.005 Visualize Results
MDP-Flow2 [64] 8.445 4.150 43.430 5.703 3.925 3.406 1.420 5.449 50.507 Visualize Results
MLDP-OF [65] 8.287 4.165 41.905 6.345 4.127 2.996 1.312 5.122 50.540 Visualize Results
PCA-Layers [66] 7.886 4.256 37.480 7.284 4.250 2.739 1.672 4.276 47.449 Visualize Results
FC-2Layers-FF [67] 8.137 4.261 39.723 6.537 4.257 2.946 1.034 4.835 51.349 Visualize Results
ComponentFusion [68] 8.231 4.274 40.460 6.221 4.252 3.193 1.702 5.701 46.696 Visualize Results
EPPM [69] 8.377 4.286 41.695 6.556 4.024 3.323 1.834 4.955 49.083 Visualize Results
Classic+NLP [70] 8.291 4.287 40.925 6.520 4.265 2.984 1.208 5.090 51.162 Visualize Results
AGIF+OF [71] 8.514 4.355 42.390 6.873 4.284 2.869 1.190 5.010 53.305 Visualize Results
COF [72] 8.204 4.448 38.805 6.788 4.500 3.324 1.561 5.560 47.534 Visualize Results
H-1px [73] 10.148 4.454 56.545 6.832 4.306 3.637 2.173 6.606 58.262 Visualize Results
CNet [74] 8.331 4.455 39.943 5.690 3.877 3.916 1.589 3.779 52.823 Visualize Results
RC-LSTM-4dir [75] 7.905 4.466 35.921 7.223 4.557 2.950 1.849 5.854 42.848 Visualize Results
SFL [76] 7.870 4.476 35.499 7.289 4.547 2.890 1.505 4.818 46.753 Visualize Results
RC-LSTM-1dir [77] 7.939 4.486 36.069 7.183 4.551 2.991 1.881 5.869 42.936 Visualize Results
RLOF_DENSE [78] 8.286 4.499 39.169 7.137 4.496 2.952 1.097 4.125 54.018 Visualize Results
SPyNet+ft [79] 8.360 4.512 39.687 6.694 4.368 3.290 1.395 5.534 49.707 Visualize Results
SPyNet [80] 8.431 4.549 40.042 6.921 4.511 3.179 1.442 5.545 50.042 Visualize Results
OAR-Flow [81] 8.179 4.578 37.525 7.146 4.611 3.131 1.316 5.593 48.445 Visualize Results
Data-Flow [82] 8.868 4.601 43.675 7.294 4.698 3.021 1.794 5.294 52.635 Visualize Results
NLTGV-SC [83] 8.746 4.635 42.242 7.084 4.749 3.391 1.587 4.780 53.860 Visualize Results
IIOF-NLDP [84] 8.715 4.705 41.403 7.280 4.778 3.265 1.263 4.538 55.795 Visualize Results
Grts-Flow-V2 [85] 8.764 4.718 41.737 6.748 4.276 3.902 2.105 6.536 47.153 Visualize Results
PCA-Flow [86] 8.652 4.725 40.671 7.602 4.818 3.196 1.961 4.524 51.844 Visualize Results
Channel-Flow [87] 8.835 4.754 42.064 6.757 4.566 3.657 1.292 5.349 54.648 Visualize Results
DF [88] 9.188 4.758 45.309 6.821 4.594 3.675 1.708 6.093 53.782 Visualize Results
DF-Beta [89] 9.196 4.765 45.327 6.829 4.603 3.677 1.706 6.085 53.877 Visualize Results
Classic+NL [90] 9.153 4.814 44.509 7.215 4.822 3.427 1.113 4.496 60.291 Visualize Results
IPOL_Brox [91] 9.198 4.869 44.479 6.856 4.682 3.789 1.679 6.106 53.956 Visualize Results
HCOF+multi [92] 8.799 4.980 39.941 7.547 4.752 3.732 1.682 5.786 51.363 Visualize Results
LDOF [93] 9.116 5.037 42.344 6.849 4.928 4.003 1.485 4.839 57.296 Visualize Results
HAST [94] 9.185 5.116 42.360 6.698 4.956 4.345 1.614 5.856 54.781 Visualize Results
ROF-NND [95] 9.286 5.130 43.129 7.561 5.350 3.796 1.221 4.700 60.367 Visualize Results
DF-Auto [96] 9.723 5.200 46.594 7.483 5.027 3.988 1.705 6.311 57.743 Visualize Results
Classic++ [97] 9.959 5.410 47.000 8.072 5.554 3.750 1.403 5.098 64.135 Visualize Results
Horn+Schunck [98] 9.610 5.419 43.734 7.950 5.658 3.976 1.882 5.335 58.274 Visualize Results
Classic+NL-fast [99] 10.088 5.659 46.145 8.010 5.738 4.160 1.092 4.666 67.801 Visualize Results
2bit-BM-tele [100] 10.978 5.793 53.220 7.710 5.603 4.814 2.338 6.959 63.521 Visualize Results
TV-L1 [101] 10.462 5.848 48.013 8.193 5.860 4.431 1.551 6.012 65.384 Visualize Results
DIS-Fast [102] 10.127 5.905 44.541 8.503 6.142 4.162 2.174 5.925 59.698 Visualize Results
UnFlow [103] 10.219 6.061 44.110 8.407 5.828 4.665 1.742 6.689 60.765 Visualize Results
PosetOptimization [104] 11.961 6.281 58.181 7.275 5.620 6.151 3.271 8.917 62.365 Visualize Results
AnisoHuber.L1 [105] 11.927 7.323 49.366 9.464 7.692 5.929 1.155 7.966 74.796 Visualize Results
Steered-L1 [106] 12.277 7.489 51.200 9.143 7.683 6.369 1.254 8.198 76.703 Visualize Results
SimpleFlow [107] 13.364 8.620 51.949 10.872 8.884 7.171 1.475 9.582 81.350 Visualize Results
AtrousFlow [108] 14.173 9.573 51.548 11.511 10.027 8.092 2.011 12.052 79.484 Visualize Results
BASELINE-Mean [109] 15.422 11.488 47.336 14.676 12.649 9.350 5.310 14.717 66.922 Visualize Results
WKSparse [110] 16.036 11.653 51.588 13.401 12.398 10.150 2.471 16.450 86.918 Visualize Results
BASELINE-zero [111] 18.926 14.396 55.633 17.050 15.613 12.172 4.049 20.873 87.342 Visualize Results
C-2px [112] 44.062 37.047 101.160 37.366 36.580 37.093 34.342 35.847 112.424 Visualize Results


Metrics


EPE Endpoint error over the complete frames
EPE matched Endpoint error over regions that remain visible in adjacent frames
EPE unmatched Endpoint error over regions that are visible only in one of two adjacent frames
d0-10 Endpoint error over regions closer than 10 pixels to the nearest occlusion boundary
d10-60 Endpoint error over regions between 10 and 60 pixels apart from the nearest occlusion boundary
d60-140 Endpoint error over regions between 60 and 140 pixels apart from the nearest occlusion boundary
s0-10 Endpoint error over regions with velocities lower than 10 pixels per frame
s10-40 Endpoint error over regions with velocities between 10 and 40 pixels per frame
s40+ Endpoint error over regions with velocities larger than 40 pixels per frame
All error images are normalized to be in the range between 0 and 1.

References
[1]
GroundTruth
[2]
FTFlow
Anonymous
[3]
DCFlow
Jia Xu, René Ranftl, Vladlen Koltun. Accurate Optical Flow via Direct Cost Volume Processing. CVPR 2017.
[4]
FlowFieldsCNN
C. Bailer, K Varanasi and D. Stricker. CNN-based Patch Matching for Optical Flow with Thresholded Hinge Embedding Loss. CVPR 2017.
[5]
InterpoNet_ff
S. Zweig, L Wolf. InterpoNet, A brain inspired neural network for optical flow dense interpolation. CVPR 2017.
[6]
PWC-Net
Anonymous. CVPR 2018 submission ID 266
[7]
ProbFlowFields
Anne S. Wannenwetsch, Margret Keuper, Stefan Roth. ProbFlow: Joint Optical Flow and Uncertainty Estimation. ICCV 2017.
[8]
S2F-IF
Yanchao Yang, Stefano Soatto. S2F: Slow-To-Fast Interpolator Flow. CVPR 2017.
[9]
SegFlow
Anonymous. CVPR 2018.
[10]
AutoScaler+
Anonymous. AutoScaler+
[11]
InterpoNet_cpm
S. Zweig, L Wolf. InterpoNet, A brain inspired neural network for optical flow dense interpolation. CVPR 2017.
[12]
FlowFields
C. Bailer, B. Taetz and D. Stricker. Flow Fields: Dense Correspondence Fields for Highly Accurate Large Displacement Optical Flow Estimation. ICCV 2015.
[13]
DeepDiscreteFlow
F. Güney and A. Geiger. Deep Discrete Flow. Asian Conference on Computer Vision (ACCV) 2016.
[14]
InterpoNet_dm
S. Zweig, L Wolf. InterpoNet, A brain inspired neural network for optical flow dense interpolation. CVPR 2017.
[15]
PGM-C
Anonymous
[16]
FlowFields+
C. Bailer, B. Taetz and D. Stricker. Optical Flow Fields: Dense Correspondence Fields for Highly Accurate Large Displacement Optical Flow Estimation. Submitted to IEEE T-PAMI.
[17]
CPM_AUG
Anonymous. CVPR 18 submission #1939
[18]
FlowNet2-ft-sintel
Anonymous. CVPR Submission #900
[19]
SPM-BPv2
Y. Li, D. Min, M. S. Brown, M. N. Do, and J. Lu. SPM-BP: Sped-up PatchMatch Belief Propagation for Continuous MRFs. ICCV 2015. Improved version. Details coming soon.
[20]
RicFlow
Yinlin Hu, Yunsong Li, Rui Song. Robust Interpolation of Correspondences for Large Displacement Optical Flow. CVPR 2017.
[21]
InterpoNet_df
S. Zweig, L Wolf. InterpoNet, A brain inspired neural network for optical flow dense interpolation. CVPR 2017.
[22]
MR-Flow
J. Wulff, L. Sevilla-Lara, M. J. Black: Optical Flow in Mostly Rigid Scenes. CVPR 2017.
[23]
FullFlow
Q. Chen, V. Koltun. Full Flow: Optical Flow Estimation By Global Optimization over Regular Grids. CVPR 2016.
[24]
DiscreteFlow+OIR
D. Maurer, M. Stoll, A. Bruhn: Order-Adaptive and Illumination Aware Variational Optical Flow Refinement. BMVC 2017.
[25]
DiscreteFlow
M. Menze, C. Heipke and A. Geiger. Discrete Optimization for Optical Flow. GCPR 2015
[26]
GlobalPatchCollider
Shenlong Wang, Sean Fanello, Christoph Rhemann, Shahram Izadi and Pushmeet Kohli, The Global Patch Collider, CVPR, 2016
[27]
NNF-Local
Anonymous. Large Displacement Optical Flow from Nearest Neighbor Fields
[28]
FlowNet2
Anonymous. CVPR Submission #900
[29]
CPM-Flow
Yinlin Hu, Rui Song, Yunsong Li. Efficient Coarse-to-Fine PatchMatch for Large Displacement Optical Flow. CVPR 2016.
[30]
Deep+R
B. Drayer and T. Brox. Combinatorial Regularization of Descriptor Matching for Optical Flow Estimation. BMVC 2015
[31]
CPM2
Coarse-to-fine PatchMatch for dense correspondence, Yunsong Li, Yinlin Hu, Rui Song, Peng Rao, Yangli Wang, submitted to T-CSVT
[32]
EpicFlow
J. Revaud, P. Weinzaepfel, Z. Harchaoui and C. Schmid. EpicFlow: Edge-Preserving Interpolation of Correspondences for Optical Flow. CVPR 2015.
[33]
DeepFlow2
J. Revaud, P. Weinzaepfel, Z. Harchaoui and C. Schmid. DeepMatching: Hierarchical Deformable Dense Matching. Submitted to IJCV.
[34]
F3-MPLF
Sathya N. Ravi, Yunyang Xiong, Lopamudra Mukherjee, Vikas Singh: Filter Flow made Practical: Massively Parallel and Lock-Free -- CVPR 2017
[35]
FGI
Y. Li, D. Min, M. N. Do, and J. Lu. Fast Guided Global Interpolation for Depth and Motion. ECCV 2016
[36]
EPMNet
Anonymous. The high accuracy for both small and large motion estimation are mainly cause by two contributions: firstly, we present and implement an edge preserve patch match (EPM) layer that propagates self-similarity patterns in addition to offsets. The accuracy of optical flow prediction has greatly improved by this method. Secondly, we develop a course-to-fine network architecture to tackle large displacement estimation and introduce a residual flow method to solve small displacement estimation.
[37]
PatchBatch+Inter
T. Schuster, L. Wolf and D. Gadot: Optical Flow Requires Multiple Strategies (but only one network). CVPR 2017.
[38]
MirrorFlow
Junhwa Hur and Stefan Roth. MirrorFlow: Exploiting Symmetries in Joint Optical Flow and Occlusion Estimation. ICCV 2017
[39]
SparseFlowFused
Radu Timofte and Luc Van Gool. SparseFlow: Sparse Matching for Small to Large Displacement Optical Flow. WACV 2015
[40]
DeepFlow
P. Weinzaepfel, J. Revaud, Z. Harchaoui and C. Schmid. DeepFlow: Large displacement optical flow with deep matching. ICCV 2013.
[41]
TF+OFM
R. Kennedy and C.J. Taylor. Optical Flow with Geometric Occlusion Estimation and Fusion of Multiple Frames. EMMCVPR 2015.
[42]
PPM
Parametric PatchMatch, Fangjun Kuang, master thesis, 2017
[43]
SPM-BP
Y. Li, D. Min, M. S. Brown, M. N. Do, and J. Lu. SPM-BP: Sped-up PatchMatch Belief Propagation for Continuous MRFs. ICCV 2015
[44]
PatchBatch-CENT+SD
Anonymous.
[45]
FALDOI
Roberto P.Palomares, Enric Meinhardt-Llopis, Coloma Ballester and Gloria Haro. FALDOI: A new minimization strategy for large displacement variational optical flow. To appear in JMIV
[46]
ZZZ
Anonymous.
[47]
PMF
J. Lu, Y. Li, H. Yang, D. Min, W. Eng, M. N. Do. PatchMatch Filter: Edge-Aware Filtering Meets Randomized Search for Visual Correspondence. TPAMI 2016
[48]
M-1px
Anonymous.
[49]
AggregFlow
D. Fortun, P. Bouthemy and C. Kervrann. Aggregation of local parametric candidates and exemplar-based occlusion handling for optical flow. CVIU 2016
[50]
BOOM+PF.XY
Fast optical flow method (0.54s single core i7 @3.1GHz) that employs the permeability filter to interpolate NNF correspondences. The NNF is an improved version of CPM that uses a new binary descriptor termed BOOM instead of SiftFlow in order to efficiently compute matching costs. Publication: Towards Edge-Aware Spatio-Temporal Filtering in Real-Time. M. Schaffner, F. Scheidegger, L. Cavigelli, H. Kaeslin, L. Benini and A. Smolic. Accepted for publication in Trans. on Image Processing (TIP), 2017. DOI: 10.1109/TIP.2017.2757259
[51]
S2D-Matching
M. Leordeanu, A. Zanfir, C. Sminchisescu. Locally Affine Sparse-to-Dense Matching for Motion and Occlusion estimation. ICCV 2013
[52]
FlowNetS+ft+v
Anonymous. ICCV submission 235
[53]
PatchWMF-OF
Zhigang Tu, Coert Van Gemeren and Remco C. Veltkamp. Improved Color Patch Similarity Measure Based Weighted Median Filter. ACCV2014
[54]
ICALD
Anonymous. EMMCVPR 2017 Submission #16.
[55]
PH-Flow
Jiaolong Yang and Hongdong Li. Dense, Accurate Optical Flow Estimation with Piecewise Parametric Model. CVPR 2015
[56]
BOOM+PF.XYT
Fast optical flow method (0.59s single core i7 @3.1GHz) that employs the permeability filter to interpolate NNF correspondences. The NNF is an improved version of CPM that uses a new binary descriptor termed BOOM instead of SiftFlow in order to efficiently compute matching costs. Publication: Towards Edge-Aware Spatio-Temporal Filtering in Real-Time. M. Schaffner, F. Scheidegger, L. Cavigelli, H. Kaeslin, L. Benini and A. Smolic. Accepted for publication in Trans. on Image Processing (TIP), 2017. DOI: 10.1109/TIP.2017.2757259
[57]
WLIF-Flow
Z. Tu, R. Poppe, and R. C. Veltkamp. Weighted local intensity fusion method for variational optical flow estimation.Pattern Recognition,2015
[58]
SparseFlow
Radu Timofte and Luc Van Gool. SparseFlow: Sparse Matching for Small to Large Displacement Optical Flow. WACV 2015
[59]
SVFilterOh
Mohamed A. Helala, Faisal Z. Qureshi, Fast Estimation of Large Displacement Optical Flow Using Dominant Motion Patterns & Sub-Volume PatchMatch Filtering, CRV 2017
[60]
AnyFlow
Anonymous. PAMI pending review
[61]
ContFusion
Anonymous. EMMCVPR 2017 submission #12
[62]
LocalLayering
D. Sun, C. Liu, and H. Pfister. Local Layering for Joint Motion Estimation and Occlusion Detection. CVPR 2014.
[63]
FlowNetC+ft+v
Anonymous. ICCV sumbmission 235
[64]
MDP-Flow2
L. Xu, J. Jia, and Y. Matsushita. Motion detail preserving optical flow estimation. PAMI 34(9):1744-1757, 2012.
[65]
MLDP-OF
M. Mohamed, H. Rashwan, B. Mertsching, M. Garcia, and D. Puig. Illumination-robust optical flow approach using local directional pattern. Accepted in IEEE TCSVT 2014.
[66]
PCA-Layers
J. Wulff and M. J. Black: Efficient sparse-to-dense optical flow estimation using a learned basis and layers. CVPR 2015.
[67]
FC-2Layers-FF
D. Sun, J. Wulff, E. Sudderth, H. Pfister, M.J. Black. A fully connected layered model of foreground and background flow. CVPR 2013
[68]
ComponentFusion
Anonymous. Fast Optical Flow by Component Fusion. Submitted to ECCV 2014. Paper ID 941.
[69]
EPPM
L. Bao, Q. Yang, and H. Jin. Fast Edge-Preserving PatchMatch for Large Displacement Optical Flow. CVPR 2014.
[70]
Classic+NLP
D. Sun, S. Roth, and M. Black. A Quantitative Analysis of Current Practices in Optical Flow Estimation and The Principles behind Them. International Journal of Computer Vision (IJCV), 106(2):115-137, 2014.
[71]
AGIF+OF
Anonymous. Signal Processing 2015
[72]
COF
H. Zimmer, A. Bruhn, J. Weickert, L. Valgaerts, A. Salgado, B. Rosenhahn, and H.-P. Seidel. Complementary optic flow. EMMCVPR 2009.
[73]
H-1px
Anonymous.
[74]
CNet
Anonymous.
[75]
RC-LSTM-4dir
Learning Contextual Dependencies for Optical Flow with Recurrent Neural Networks (ACCV 2016)
[76]
SFL
Jingchun Cheng, Yi-Hsuan, Tsai, Shengjin Wang, Ming-Hsuan Yang. SegFlow: Joint Learning for Video Object Segmentation and Optical Flow. ICCV 2017
[77]
RC-LSTM-1dir
Learning Contextual Dependencies for Optical Flow with Recurrent Neural Networks (ACCV 2016)
[78]
RLOF_DENSE
Jonas Geistert, Tobias Senst and Thomas Sikora, Robust Local Optical Flow: Dense Motion Vector Field Interpolation, PCS 2016
[79]
SPyNet+ft
Ranjan, Anurag and Black, Michael J., Optical Flow Estimation using a Spatial Pyramid Network, Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, 2017
[80]
SPyNet
Ranjan, Anurag and Black, Michael J., Optical Flow Estimation using a Spatial Pyramid Network, Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, 2017
[81]
OAR-Flow
D. Maurer, M. Stoll, A. Bruhn: Order-Adaptive Regularisation for Variational Optical Flow: Global, Local and in Between. SSVM 2017.
[82]
Data-Flow
Anonymous. CSAD data cost + second order smoothness
[83]
NLTGV-SC
R. Ranftl, K. Bredies, T. Pock. Non-Local Total Generalized Variation for Optical Flow Estimation, ECCV 2014
[84]
IIOF-NLDP
Dinh-Hoan Trinh, Walter Blondel, and Christian Daul. A General Form of Illumination-Invariant Descriptors in Variational Optical Flow Estimation. ICIP 2017.
[85]
Grts-Flow-V2
En Zhu, Yuanwei Li, Yanling Shi. Fast Optical Flow Estimation without Parallel Architectures. TCSVT
[86]
PCA-Flow
J. Wulff and M. J. Black: Efficient sparse-to-dense optical flow estimation using a learned basis and layers. CVPR 2015.
[87]
Channel-Flow
L. Sevilla-Lara, D. Sun, E. Learned-Miller, and M. Black. Optical Flow Estimation with Channel Constancy. ECCV, pages 423-438, 2014.
[88]
DF
Nelson Monzón, Agustín Salgado and Javier Sánchez. Regularization Strategies for Discontinuity-Preserving Optical Flow Methods. IEEE Transactions on Image Processing, Vol 25(4), pp. 1580 - 1591, 2016
[89]
DF-Beta
Nelson Monzón, Agustín Salgado and Javier Sánchez. Regularization Strategies for Discontinuity-Preserving Optical Flow Methods. IEEE Transactions on Image Processing, Vol 25(4), pp. 1580 - 1591, 2016
[90]
Classic+NL
D. Sun, S. Roth, and M. Black. Secrets of optical flow estimation and their principles. CVPR, pages 2432-2439, 2010.
[91]
IPOL_Brox
J. Sánchez, N. Monzón, and A. Salgado, Robust Optical Flow Estimation, Image Processing On Line (IPOL), 3 (2013), pp. 252–270.
[92]
HCOF+multi
R. Kennedy and C. J. Taylor. Hierarchically-Constrained Optical Flow. CVPR 2015.
[93]
LDOF
T. Brox, J. Malik. IEEE Transactions on Pattern Analysis and Machine Intelligence, 33(3): 500-513, 2011.
[94]
HAST
Yinlin Hu, Rui Song, Yunsong Li, Peng Rao, Yangli Wang. Highly Accurate Optical Flow Estimation on Superpixel Tree. Image and Vision Computing (IVC), 2016
[95]
ROF-NND
Sharib Ali, Christian Daul, Ernest Galbrun, Walter Blondel, Illumination invariant optical flow using neighborhood descriptors, Computer Vision and Image Understanding, Available online 17 December 2015, ISSN 1077-3142.
[96]
DF-Auto
Nelson Monzón, Agustín Salgado and Javier Sánchez. Regularization Strategies for Discontinuity-Preserving Optical Flow Methods. IEEE Transactions on Image Processing, Vol 25(4), pp. 1580 - 1591, 2016
[97]
Classic++
D. Sun, S. Roth, and M. Black. Secrets of optical flow estimation and their principles. CVPR, pages 2432-2439, 2010.
[98]
Horn+Schunck
A modern Matlab implementation of the Horn & Schunck method by Deqing Sun.
[99]
Classic+NL-fast
D. Sun, S. Roth, and M. Black. Secrets of optical flow estimation and their principles. CVPR, pages 2432-2439, 2010.
[100]
2bit-BM-tele
Rui Xu & David Taubman, Robust Dense Block-Based Motion Estimation Using a Two-Bit Transform on a Laplacian Pyramid, ICIP 2013 +telescopic search
[101]
TV-L1
Anonymous. It is a well-known model that uses TV-L1 (coupled) as the regularization term and an L1 data term.
[102]
DIS-Fast
T. Kroeger, R. Timofte, D. Dai, L. Van Gool, Fast Optical Flow using Dense Inverse Search. ECCV 2016. Run-time: 0.023 s (20ms preprocessing, 3ms flow computation). Using operating point 2 of the paper.
[103]
UnFlow
Anonymous.
[104]
PosetOptimization
Anonymous.
[105]
AnisoHuber.L1
M. Werlberger, W. Trobin, T. Pock, A. Wedel, D. Cremers, and H. Bischof. Anisotropic Huber-L1 optical flow. BMVC 2009.
[106]
Steered-L1
Anonymous.
[107]
SimpleFlow
M. W. Tao, J. Bai, P. Kohli, and S. Paris. "SimpleFlow: A Non-iterative, Sublinear Optical Flow Algorithm". Computer Graphics Forum (Eurographics 2012), 2012. (OpenCV 2.4.5 Implementation, parameters provided by OpenCV sample)
[108]
AtrousFlow
Anonymous. Real-time dense optical flow using CUDA
[109]
BASELINE-Mean
[110]
WKSparse
[111]
BASELINE-zero
[112]
C-2px
Anonymous.