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Efficient High-Resolution Stereo Matching using Local Plane Sweeps Sudipta N. Sinha, Daniel Scharstein, Richard Szeliski @ CVPR 2014 Yongho Shin.

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Presentation on theme: "Efficient High-Resolution Stereo Matching using Local Plane Sweeps Sudipta N. Sinha, Daniel Scharstein, Richard Szeliski @ CVPR 2014 Yongho Shin."β€” Presentation transcript:

1 Efficient High-Resolution Stereo Matching using Local Plane Sweeps Sudipta N. Sinha, Daniel Scharstein, Richard CVPR 2014 Yongho Shin

2 𝑂(π‘Šπ»π‘π·) 𝑂( 2 10 π‘Šπ»π‘π·) Problems
High-resolution images require long time for computing a disparity map Complexity for general local methods for 2x size images 𝑂(π‘Šπ»π‘π·) 𝑂( 2 10 π‘Šπ»π‘π·) This is a problem of this paper. If we use the high resolution image, it requires a lot of time for calculating disparity map. For example, we have image scaled up 4 times, and we needs almost 1000 times time. x4

3 Related works 𝑂(π‘Šπ»π·) Semi-global matching
Optimize following energy function 𝐸=𝐸 π‘‘π‘Žπ‘‘π‘Ž +𝐸( 𝐷 𝑝 βˆ’ 𝐷 π‘ž =1)+𝐸( 𝐷 𝑝 βˆ’ 𝐷 π‘ž >1) NP-hard problem!! Approximate methods operate in adequate computing time, but still slow Dynamic programming gives faster way, but erroneous result Instead do dynamic programming along many directions It cannot model second-order smoothness 𝑂(π‘Šπ»π·) For efficiently capturing disparity map, a lot of athors give a good manners. One of the good method is a SGM. SGM is the optimization technique. It minimize following energy function. But this energy function is NP –hard problem.

4 Related works Efficient large-scale stereo matching
Stereo matching based on search space reduction Computation GCPs Delaunay triangulation on GCPs Matching on triangles with restricted range

5 Segment-Based Stereo Matching Using Belief Propagation
Very related work

6 Matching with a segmentation
Initial matching Any matching method can be used Initial matching Extraction of reliable pixels model parameter from each segment Assignment of optimal parameter for each segment by BP Noisy result

7 Matching with a segmentation
Extraction of reliable pixels Simple cross checking method is used Occlusion region can be detected Initial matching Extraction of reliable pixels model parameter from each segment Assignment of optimal parameter for each segment by BP Left image Right image Left result Right result

8 Matching with a segmentation
Extraction of model parameter from each segment At each segment, a model parameter is extracted using reliable pixels and robust statistical technique Add the parameter to a parameter set Initial matching Extraction of reliable pixels model parameter from each segment Assignment of optimal parameter for each segment by BP Reliable pixels Segments

9 Matching with a segmentation
Extraction of model parameter from each segment At each segment, a model parameter is extracted using reliable pixels and robust statistical technique Add the parameter to a parameter set Initial matching Extraction of reliable pixels model parameter from each segment Assignment of optimal parameter for each segment by BP Parameter Parameter Set

10 Matching with a segmentation
Assignment of optimal parameter for each segment by BP Assign an optimal parameter for each segment as total energy can be minimized Initial matching Extraction of reliable pixels model parameter from each segment Assignment of optimal parameter for each segment by BP Parameter #29 Parameter #29 Parameter Set

11 Matching with a segmentation
b c d a : Initial disparity map b : Interpolated result c : Reliable pixel map d : Result from a segmentation

12 Matching with a segmentation
What they did Make plane parameter by segment and initial disparity map Find optimal plane parameters for each segment of the image Select optimal parameters by BP

13 Proposed method

14 Information for understanding
What they do Make plane parameter by feature points Find optimal plane parameters for each tiles of the image Allowing objects having curved surface Select optimal parameters by SGM

15 Hypothesis generation
Proposed method

16 Hypothesis generation
Feature matching By Harris corner keypoints and upright DAISY descriptors Matching only points along near epipolar line Due to stereo matching But, they allow small vertical misalignments First round Initial set of matches are selected using the ratio test heuristic Second round For obtaining more matched features Horizontal search range is reduced using local estimates

17 Hypothesis generation
Vertical alignment Correct for small vertical misalignments from errors in rectification By fitting a global linear model using RANSAC with matched features 𝑑 𝑦 =π‘Žπ‘¦+𝑏

18 Hypothesis generation
Disparity plane estimation Cluster matched points and find plane parameters Find k number of planes Using variational approach used for mesh simplification Graph based approach with priority queue

19 Local plane sweeps Proposed method

20 Local plane sweep Plane for tiles having parallax
Because there are curved objects in the world Hence, gives range of Β±T pixels of parallax from plane For each plane, investigate similarity among range 2T Optimize by SGM

21 Local plane sweep Identifying in-range disparities
By disparity map, they give cost U AD NCC JUMP

22 Proposal generation Proposed method

23 Proposal generation Initial proposals Online proposals
Find the planes with associated points within each tile Online proposals Find frequent plane parameter for each tile Propagate the parameter to neighbors

24 Global optimization Proposed method

25 Power SGM!! Global optimization We have Plane parameters for each tile
Cost U Energy function Power SGM!!

26 Experiments

27 Quantitative results

28 Qualitative results

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