Problems with template matching
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- Valerie Cain
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1 Problems with template matching The template represents the object as we expect to find it in the image The object can indeed be scaled or rotated This technique requires a separate template for each scale and orientation Template matching become thus too expensive, especially for large templates Sensitive to: noise occlusions SINA 11/1
2 Local template matching A possible solution is to reduce the size of the templates, and detect salient features in the image that characterize the object we are interested in Extract a set of local features that are invariant to translation, rotation and scale Perform matching only on these local features We then analyze the spatial relationships between those features See for example: Corner detector (Harris and Stephens,1988) SIFT (Lowe, 1999) SINA 11/1
3 Image content is transformed into local feature coordinates that are invariant to translation, rotation, scale, and other imaging parameters SINA 11/1
4 Applications Object recognition 3D reconstruction Motion detection Panorama reconstruction SINA 11/1
5 How do we build a panorama? We need to match (align) images SINA 11/1
6 Matching with Features Detect feature points in both images Find corresponding pairs SINA 11/1
7 Matching with Features Detect feature points in both images Find corresponding pairs Use these pairs to align images SINA 11/1
8 Matching with Features Problem 1: Detect the same point independently in both images no chance to match! We need a repeatable detector SINA 11/1
9 Matching with Features Problem : For each point correctly recognize the corresponding one? We need a reliable and distinctive descriptor SINA 11/1
10 Moravec interest operator This operator was developed back in 1977 for navigation Defines points of interest regions in the image that are good candidates for matching in consecutive image frames It is considered a corner detection since it defines interest points as points in which there is large intensity variation in every direction SINA 11/1
11 Place a small square window (3x3, 5x5, 7x7 ) centered at a point P Shift this window by one pixel in each of eight principle directions (four diagonals, horizontal and vertical) Take the sum of squares of intensity differences of corresponding pixels in these two windows Define the intensity variation V as the minimum intensity variation over the eight principle directions SINA 11/1
12 SINA 11/1
13 for each x,y in the image Algorithm V x y I x u a y v b I x a y b (, ) (, ) (, ) uv, ab, ( uv, ) are the considered shifts: 1,0, 1,1, 0,1,( 1,1),( 1,0),( 1, 1),(0, 1),(1, 1) C( x, y) min( V ( x, y)) uv, threshold, set C(x,y) to zero of C(x,y)<T non-maximal suppression to find local maxima SINA 11/1
14 Non maximal suppression 1 if V( x, y) V( p, q), ( p, q) N( x, y) I( x, y) 0 otherwise SINA 11/1
15 Source: Results SINA 11/1
16 Noise sensitivity Small imperfection in edges will be picked up as corners Edges not oriented along one of the height directions will also be candidate corners SINA 11/1
17 Harris and Stephens Similarly to Moravec, consider now a continuous function: E ( x) I( x d) I( x dh) h dh, R dw x ( x, y) R Perform local Taylor expansion: T T I( x h) I( x) I( x) h I( x h) I( x) I( x) h I( x) I( x) I( x), x y T SINA 11/1
18 T T T E ( x) I( x d) h h I( x d) I( x d) h h dw Ix I T xi y h h dw I xiy Iy I T W x I W xi y h h I W xi y I W y dw It is possible to introduce a weighting window w() for each point. For example a Gaussian: I I x y I( xd) x I( xd) y w() d 1 d e SINA 11/1
19 and compute the filtered variation ˆ T E ( x) h Ch ˆ h ( ) ( ) ˆ Ixw d IxIyw d C the eigenvalues of C will be proportional to the principle curvatures of the image surface and form a rotationally invariant description of C from linear algebra: E h 1 1 ( x) v v SINA 11/1
20 no structure or 0 and 1 Three cases 0 edge 1 0 corner SINA 11/1
21 SINA 11/1 define the following index R usually, k=0.04 trace and determinant are preserved t C C 1 1 ˆ ˆ ˆ det ˆ ˆ ˆ ˆ ˆ) det( y x y x y x I I I I C I I C tr C tr k C R
22 R(x,y) for k=0. SINA 11/1
23 SINA 11/1
24 SINA 11/1
25 Source: Results SINA 11/1
26 Problems Moravec and Harris have problems with rotations SINA 11/1
27 The scale problem SINA 11/1
28 Other features SINA 11/1
29 H L L xx xy L L L tr( H ) det( H ) xx xy yy L L xx yy L L yy xy Responds to bolb-like structures, but also to edges Responds to bolb-like structures, and saddles, insensitive to edges SINA 11/1
30 Search across scale A common approach is to search for maxima across scales Since the amplitude of spatial derivatives decreases with scale, the amplitude of features is expected to decrease Define normalized features: norm det( H tr( H norm ) t norm ) L t xx L yy L xx L L xy yy Lindeberg, Feature Detection With Automatic Scale Selection, Int. Journal of Computer Vision, 1998 SINA 11/1
31 SINA 11/1
32 SINA 11/1
33 Material from: Lecture 10, Advances in Computer Vision, MIT (online). Harris, C. and Stephens, M., A Combined Corner and Edge Detector, Proceedings of the 4th Alvey Vision Conference, pp , 1988 D.Lowe and Cordelia Schmid, Recognition and Matching based on local invariant features, CVPR 003 Lowe, D., Object Recognition from Local Scale-Invariant Features, Proc. Of the International Conference on Computer Vision, Corfu, September 1999 Lindeberg, T., Edge and Ridge Detection with Automatic Scale Selection, Intl. Journal of Computer Vision 30(), , 1998 Lindeberg, T., Feature Detection With Automatic Scale Selection, Int. Journal of Computer Vision, 30(), , 1998 Lindeberg, T., Scale-space, In Encyclopedia of Computer Science and Engineering, 008 SINA 11/1
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