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Robust and large-scale alignment

Robust and large-scale alignment. Image from http://graphics.cs.cmu.edu/courses/15-463/2010_fall/. Robust feature-based alignment. So far, we’ve assumed that we are given a set of “ground-truth” correspondences between the two images we want to align What if we don’t know the correspondences?.

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Robust and large-scale alignment

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  1. Robust and large-scale alignment Image from http://graphics.cs.cmu.edu/courses/15-463/2010_fall/

  2. Robust feature-based alignment • So far, we’ve assumed that we are given a set of “ground-truth” correspondences between the two images we want to align • What if we don’t know the correspondences?

  3. Robust feature-based alignment • So far, we’ve assumed that we are given a set of “ground-truth” correspondences between the two images we want to align • What if we don’t know the correspondences? ?

  4. Robust feature-based alignment

  5. Robust feature-based alignment • Extract features

  6. Robust feature-based alignment • Extract features • Compute putative matches

  7. Robust feature-based alignment • Extract features • Compute putative matches • Loop: • Hypothesize transformation T

  8. Robust feature-based alignment • Extract features • Compute putative matches • Loop: • Hypothesize transformation T • Verify transformation (search for other matches consistent with T)

  9. Robust feature-based alignment • Extract features • Compute putative matches • Loop: • Hypothesize transformation T • Verify transformation (search for other matches consistent with T)

  10. Generating putative correspondences ?

  11. ( ) ( ) Generating putative correspondences • Need to compare feature descriptors of local patches surrounding interest points ? ? = featuredescriptor featuredescriptor

  12. Feature descriptors • Recall: covariant detectors => invariant descriptors Compute appearancedescriptors Detect regions Normalize regions

  13. Feature descriptors • Simplest descriptor: vector of raw intensity values • How to compare two such vectors? • Sum of squared differences (SSD) • Not invariant to intensity change • Normalized correlation • Invariant to affine intensity change

  14. Disadvantage of intensity vectors as descriptors • Small deformations can affect the matching score a lot

  15. Feature descriptors: SIFT • Descriptor computation: • Divide patch into 4x4 sub-patches • Compute histogram of gradient orientations (8 reference angles) inside each sub-patch • Resulting descriptor: 4x4x8 = 128 dimensions David G. Lowe. "Distinctive image features from scale-invariant keypoints.”IJCV 60 (2), pp. 91-110, 2004.

  16. Feature descriptors: SIFT • Descriptor computation: • Divide patch into 4x4 sub-patches • Compute histogram of gradient orientations (8 reference angles) inside each sub-patch • Resulting descriptor: 4x4x8 = 128 dimensions • Advantage over raw vectors of pixel values • Gradients less sensitive to illumination change • Pooling of gradients over the sub-patches achieves robustness to small shifts, but still preserves some spatial information David G. Lowe. "Distinctive image features from scale-invariant keypoints.”IJCV 60 (2), pp. 91-110, 2004.

  17. Feature matching • Generating putative matches: for each patch in one image, find a short list of patches in the other image that could match it based solely on appearance ?

  18. Feature space outlier rejection • How can we tell which putative matches are more reliable? • Heuristic: compare distance of nearest neighbor to that of second nearest neighbor • Ratio of closest distance to second-closest distance will be highfor features that are not distinctive • Threshold of 0.8 provides good separation David G. Lowe. "Distinctive image features from scale-invariant keypoints.”IJCV 60 (2), pp. 91-110, 2004.

  19. Reading David G. Lowe. "Distinctive image features from scale-invariant keypoints.”IJCV 60 (2), pp. 91-110, 2004.

  20. RANSAC • The set of putative matches contains a very high percentage of outliers • RANSAC loop: • Randomly select a seed group of matches • Compute transformation from seed group • Find inliers to this transformation • If the number of inliers is sufficiently large, re-compute least-squares estimate of transformation on all of the inliers • Keep the transformation with the largest number of inliers

  21. RANSAC example: Translation Putative matches

  22. RANSAC example: Translation Select one match, count inliers

  23. RANSAC example: Translation Select one match, count inliers

  24. RANSAC example: Translation Select translation with the most inliers

  25. Scalability: Alignment to large databases • What if we need to align a test image with thousands or millions of images in a model database? • Efficient putative match generation • Approximate descriptor similarity search, inverted indices Test image ? Model database

  26. Scalability: Alignment to large databases • What if we need to align a test image with thousands or millions of images in a model database? • Efficient putative match generation • Fast nearest neighbor search, inverted indexes Test image D. Nistér and H. Stewénius, Scalable Recognition with a Vocabulary Tree, CVPR 2006 Vocabulary tree with inverted index Database

  27. Descriptor space Slide credit: D. Nister

  28. Hierarchical partitioning of descriptor space (vocabulary tree) Slide credit: D. Nister

  29. Vocabulary tree/inverted index Slide credit: D. Nister

  30. Populating the vocabulary tree/inverted index Model images Slide credit: D. Nister

  31. Model images Populating the vocabulary tree/inverted index Slide credit: D. Nister

  32. Model images Populating the vocabulary tree/inverted index Slide credit: D. Nister

  33. Model images Populating the vocabulary tree/inverted index Slide credit: D. Nister

  34. Test image Model images Looking up a test image Slide credit: D. Nister

  35. Voting for geometric transformations • Modeling phase: For each model feature, record 2D location, scale, and orientation of model (relative to normalized feature coordinate frame) index model

  36. Voting for geometric transformations • Test phase: Each match between a test and model feature votes in a 4D Hough space (location, scale, orientation) with coarse bins • Hypotheses receiving some minimal amount of votes can be subjected to more detailed geometric verification index test image model

  37. Indexing with geometric invariants • When we don’t have feature descriptors, we can take n-tuples of neighboring features and compute invariant features from their geometric configurations • Application: searching the sky: http://www.astrometry.net/ B C D A

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