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Interactive Graph Cuts for Segmentation in N-D Images

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Title: Interactive Graph Cuts for Segmentation in N-D Images


1
Interactive Graph Cuts for Segmentation in N-D
Images
Yuri Boykov, Marie-Piere Jolly
Mohit Gupta 02/15/2006 Advanced Perception
2
Image Segmentation
Images Label Me Database
3
Focus of this work Foreground vs. Background
  • The framework presented can be easily extended
    to multi-label segmentation though
  • Multi-label segmentation solved by iteratively
    solving many 2-label
  • sub-problems (Boykov, Veksler, Zabih)

Images Yin Li et al (Lazy Snapping)
4
Focus of this work Foreground vs. Background
  • The framework presented can be easily extended
    to multi-label segmentation though
  • Multi-label segmentation solved by iteratively
    solving many 2-label
  • sub-problems (Boykov, Veksler, Zabih)

Supervised Method
Images Yin Li et al (Lazy Snapping)
5
Taxonomy Previous Work
  • Fully Automatic Methods
  • EigenVectors Based approaches (Normalized Cuts,
    Perona and Freeman Algorithm etc.)
  • Supervised Methods
  • Boundary Based approaches use of an evolving
    curve (snakes, intelligent scissor, image
    snapping)
  • Region Based approaches hints about foreground
    vs. background (intelligent paint, GrabCut)

6
Taxonomy Previous Work
A Gradient based vector-field
  • Fully Automatic Methods
  • EigenVectors Based approaches (Normalized Cuts,
    Perona and Freeman Algorithm etc.)
  • Supervised Methods
  • Boundary Based approaches use of an evolving
    curve (snakes, intelligent scissor, image
    snapping)
  • Region Based approaches hints about foreground
    vs. background (intelligent paint, GrabCut)

7
Taxonomy Previous Work
Edge Weights depend on the boundary-ness
High probability of boundary ? Low weight
  • Fully Automatic Methods
  • EigenVectors Based approaches (Normalized Cuts,
    Perona and Freeman Algorithm etc.)
  • Supervised Methods
  • Boundary Based approaches use of an evolving
    curve (snakes, intelligent scissor, image
    snapping)
  • Region Based approaches hints about foreground
    vs. background (intelligent paint, GrabCut)

8
Taxonomy Previous Work
Boundary Shortest Path between graph vertices
  • Fully Automatic Methods
  • EigenVectors Based approaches (Normalized Cuts,
    Perona and Freeman Algorithm etc.)
  • Supervised Methods
  • Boundary Based approaches use of an evolving
    curve (snakes, intelligent scissor, image
    snapping)
  • Region Based approaches hints about foreground
    vs. background (intelligent paint, GrabCut)

9
Taxonomy Previous Work
  • Fully Automatic Methods
  • EigenVectors Based approaches (Normalized Cuts,
    Perona and Freeman Algorithm etc.)
  • Supervised Methods
  • Boundary Based approaches use of an evolving
    curve (snakes, intelligent scissor, image
    snapping)
  • Region Based approaches hints about foreground
    vs. background (intelligent paint, GrabCut)

10
Case for a Supervised, Region Based Method
  • Fully Automatic
  • Never perfect Hard to get
  • crisp boundaries for inherently
  • ambiguous, low contrast images
  • Boundary Based Supervised
  • Complex Object Users nightmare

"Whenever something can be done in two ways,
someone will be confused. Whenever something is a
matter of taste, discussions can drag on
forever." -- Bjarne Stroustrup
11
Interactive Graph Cuts Overview
  • Supervised Region based segmentation technique
  • What user does?
  • Provide clues as to the
    desired segmentation
  • Foreground and
    Background seed
    pixels
  • Energy of the segmentation
  • Lower the energy, better the segmentation

12
Problem Formulation
  • Input
  • Set of pixels P,
  • Neighborhood system
    N p,q
  • Hard Constraints clues
    for segmentation
  • Objective function Soft Constraint (Energy)
  • Output
  • Assignment vector A (A1, , Ap , , AP),
    where Ai e 0,1
  • A defines a segmentation of the image

13
Objective FunctionEnergy of the Segmentation
TO DO Minimize Energy E(A) while satisfying the
hard constraints
  • Regional Term R(A) ? Cost for assigning labels
    to individual pixels
  • Boundary Term B(A) ? Cost for making the
    boundary pass between
  • two given
    pixels

14
Graph Cuts and Image Segmentation
  • A node for every pixel
  • Two terminal nodes
  • n-links and t-links
  • Edge weights

15
Min-Cut Energy Minimization
  • Graph Cut
  • Segmentation
  • A (A1, , Ap , , AP)

16
Min-Cut Energy Minimization
  • Graph Cut
  • Segmentation
  • A (A1, , Ap , , AP)
  • C E(A)
  • Min C min E(A)

17
Min-Cut Energy Minimization
  • Graph Cut
  • Segmentation
  • A (A1, , Ap , , AP)
  • C E(A)
  • Min C min E(A)

Min-cut Optimal Segmentation!
18
Implementation
  • User Marked Seeds provide
  • foreground and background intensity
    distributions
  • in addition to hard constraints
  • Color, Texture, intensity, location as features

19
Results
  • Low values of l
  • Boundary term dictates
  • Region Shrinking
  • High values of l
  • Region term dictates
  • Neighborhood info ignored

20
We dont want toy results
  • Start with a few obj and bckg seeds
  • Refinement in trouble places

Images Yin Li et al (Lazy Snapping)
21
Interactivity
New obj/bckg pixel added/deleted
Only two links change
Real time re-computation Possible ? Interactive!
22
More Results
Images Yin Li et al (Lazy
Snapping), Boykov and Jolly
23
Performance
  • Efficient polynomial time algorithms available
    for min-cut
  • Segmentation Problem ? Sparse graphs
  • Computations in the blink of an eye
  • Efficiency measured in terms of amount of human
    effort
  • Bell Example takes about a minute

24
Markov Random Fields (MRFs)
  • S discrete set of sites S 1, , m
  • Ld discrete set of labels, eg. 1, L.
  • Neighborhood system N
  • A labeling assigns a label to every site,
  • f f1, fm. fi is the label of site i.
  • Neighborhood ? conditional independence
  • F is an MRF on S w.r.t. N iff
  • P(f) gt 0
  • P(fi fS-i) P(fi fNi)

25
Lazy Snapping (SIGGRAPH2004)
Yin Li, Jian Sun, Chi-Keung Tang, Heung-Yeung
Shum(MSRA)
  • Refine the coarse results returned by Graph-Cut
    Based methods (Boykov and Jolly)
  • Extremely Fast
  • Commercial System ? User Friendly

26
Modus Operandi How does it work?
  • Supervised Region Based Method
  • Three Step Process
  • Pre-segmentation ( super pixels )
  • Object Marking Step ( a la Boykov and Jolly)
  • Local Refinement Step

27
Pre-segmentation
  • Exploit Spatial Coherency ? Replace Pixels by
    Super-Pixels
  • Aggressive unsupervised segmentation ?
    preserves color coherency within regions

28
Pre-segmentation
29
Object Marking Step
Similar to Boykov and Jolly
Different Penalty Functions
More similar a node to obj / bckg, lesser the
corresponding energy term
More similar the nodes, larger the boundary
energy term
30
Boundary Editing
  • Object Boundary from previous step represented as
    polygon
  • Polygon can be edited for local refinement
  • Local refinement ? New constraints
  • Another optimization for better fit

31
Boundary Editing
  • Dij term penalizes a node pair far away from the
    polygon ? brings boundary closer to the polygon

b 1 ? boundary snaps to polygon
Important The optimized boundary snaps to the
object boundary even though the polygon vertices
may not be on it.
32
citius altius fortius
  • Faster, easier, accurater

33
The pretty SIGGRAPH video
34
Multi-way graph cuts(Boykov, Veksler, Zabih)
Images Label Me Database
35
Multi-way graph cuts
Slides Yuri Boykov
36
Multi-way graph cuts
  • BAD NEWS
  • NP-hard problem (3 or more labels)
  • two labels can be solved in polynomial time via
    s-t cuts
  • GOOD NEWS
  • a-expansion approximation algorithm
  • guaranteed approximation quality (2-approx)

Slides Yuri Boykov
37
Multi-way graph cuts
  • NP-hard problem (3 or more labels)
  • two labels can be solved via s-t cuts
  • a-expansion approximation algorithm
  • guaranteed approximation quality (2-approx)
  • a-expansion move

Slides Yuri Boykov
38
a-expansion move
Basic idea
break multi-way cut computation into a sequence
of binary s-t cuts
Slides Yuri Boykov
39
a-expansion move
Basic idea
break multi-way cut computation into a sequence
of binary s-t cuts
Iteratively, each label competes with other
labels for space in the image
40
a-expansion algorithm
  • Start with any initial solution
  • For each label a in any (e.g. random) order
  • Compute optimal a-expansion move (s-t graph cuts)
  • Decline the move if there is no energy decrease
  • Stop when no expansion move would decrease energy

Slides Yuri Boykov
41
a-expansion algorithm
  • Start with any initial solution
  • For each label a in any (e.g. random) order
  • Compute optimal a-expansion move (s-t graph cuts)
  • Decline the move if there is no energy decrease
  • Stop when no expansion move would decrease energy

A 2-approx algorithm for an NP-complete
problem! Converges in a few iterations!
42
Video Segmentation
Video Object Cut and Paste (SIGGRAPH2004)
Yin Li, Jian Sun, Heung-Yeung Shum(MSRA)
43
Climbing the dimension ladder2D ? 3D
  • Video Segmentation 3D graph on volume
    of frames
  • Edges for temporal coherence in addition to
    spatial coherence
  • obj bckg seeds on a few key-frames

Image Yin Li et al
44
Whats new? Temporal Coherence
Our old friend
45
Local Refinement Problem
  • obj / bckg color models built globally from
    key frames
  • Might get confused between the two !

46
Local Refinement Solution
  • Mark windows around problem areas in key frames
  • Windows propagate through middle frames using a
    feature tracking algorithm
  • Apply 2D pixel level graph cut segmentation
  • Important Seeds generated automatically

47
Video Segmentation Results
Images Boykov and Jolly
48
Another (obviously pretty) SIGGRAPH video
49
Conclusion
  • Merits
  • Globally Optimum Segmentation, when cost function
    is clearly defined (normalized cuts only give an
    approximate solution)
  • Very Fast Interactive Rates
  • Natural Extension to N-Dimensional images
  • Easily Editable More user friendly
  • Possible Improvement
  • Automatic Seed Selection From Coarse (LabelMe)
    kind of segmentation
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