Fitting: Deformable contours Tuesday, September 24 th 2013 Devi Parikh Virginia Tech 1 Slide credit: Kristen Grauman Disclaimer: Many slides have been.

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Presentation transcript:

Fitting: Deformable contours Tuesday, September 24 th 2013 Devi Parikh Virginia Tech 1 Slide credit: Kristen Grauman Disclaimer: Many slides have been borrowed from Kristen Grauman, who may have borrowed some of them from others. Any time a slide did not already have a credit on it, I have credited it to Kristen. So there is a chance some of these credits are inaccurate.

Recap so far: Grouping and Fitting Goal: move from array of pixel values (or filter outputs) to a collection of regions, objects, and shapes. 2 Slide credit: Kristen Grauman

Grouping: Pixels vs. regions imageclusters on intensity clusters on color image By grouping pixels based on Gestalt- inspired attributes, we can map the pixels into a set of regions. Each region is consistent according to the features and similarity metric we used to do the clustering. Kristen Grauman 3

Fitting: Edges vs. boundaries Edges useful signal to indicate occluding boundaries, shape. Here the raw edge output is not so bad… …but quite often boundaries of interest are fragmented, and we have extra “clutter” edge points. Images from D. Jacobs Kristen Grauman 4

Given a model of interest, we can overcome some of the missing and noisy edges using fitting techniques. With voting methods like the Hough transform, detected points vote on possible model parameters. Fitting: Edges vs. boundaries Kristen Grauman 5

Voting with Hough transform Hough transform for fitting lines, circles, arbitrary shapes x y image space x0x0 y0y0 (x 0, y 0 ) (x 1, y 1 ) m b Hough space In all cases, we knew the explicit model to fit. Kristen Grauman 6

Fitting an arbitrary shape with “active” deformable contours Today 7 Slide credit: Kristen Grauman

Deformable contours a.k.a. active contours, snakes Given: initial contour (model) near desired object [Snakes: Active contour models, Kass, Witkin, & Terzopoulos, ICCV1987] Figure credit: Yuri Boykov 8 Slide credit: Kristen Grauman

Deformable contours Given: initial contour (model) near desired object a.k.a. active contours, snakes Figure credit: Yuri Boykov Goal: evolve the contour to fit exact object boundary [Snakes: Active contour models, Kass, Witkin, & Terzopoulos, ICCV1987] Main idea: elastic band is iteratively adjusted so as to be near image positions with high gradients, and satisfy shape “preferences” or contour priors 9 Slide credit: Kristen Grauman

Deformable contours: intuition Image from Kristen Grauman 10

Deformable contours vs. Hough initial intermediate final Like generalized Hough transform, useful for shape fitting; but Hough Rigid model shape Single voting pass can detect multiple instances Deformable contours Prior on shape types, but shape iteratively adjusted (deforms) Requires initialization nearby One optimization “pass” to fit a single contour Kristen Grauman 11

Why do we want to fit deformable shapes? Some objects have similar basic form but some variety in the contour shape. Kristen Grauman 12

Why do we want to fit deformable shapes? Non-rigid, deformable objects can change their shape over time, e.g. lips, hands… Figure from Kass et al Kristen Grauman 13

Why do we want to fit deformable shapes? Non-rigid, deformable objects can change their shape over time, e.g. lips, hands… Kristen Grauman 14

Figure credit: Julien Jomier Why do we want to fit deformable shapes? Non-rigid, deformable objects can change their shape over time. Kristen Grauman 15

Aspects we need to consider Representation of the contours Defining the energy functions –External –Internal Minimizing the energy function Extensions: –Tracking –Interactive segmentation Kristen Grauman 16

Representation We’ll consider a discrete representation of the contour, consisting of a list of 2d point positions (“vertices”). for At each iteration, we’ll have the option to move each vertex to another nearby location (“state”). Kristen Grauman 17

Fitting deformable contours initial intermediate final How should we adjust the current contour to form the new contour at each iteration? Define a cost function (“energy” function) that says how good a candidate configuration is. Seek next configuration that minimizes that cost function. 18 Slide credit: Kristen Grauman

Energy function The total energy (cost) of the current snake is defined as: A good fit between the current deformable contour and the target shape in the image will yield a low value for this cost function. Internal energy: encourage prior shape preferences: e.g., smoothness, elasticity, particular known shape. External energy (“image” energy): encourage contour to fit on places where image structures exist, e.g., edges. 19 Slide credit: Kristen Grauman

External energy: intuition Measure how well the curve matches the image data “Attract” the curve toward different image features –Edges, lines, texture gradient, etc. 20 Slide credit: Kristen Grauman

External image energy Magnitude of gradient - (Magnitude of gradient) How do edges affect “snap” of rubber band? Think of external energy from image as gravitational pull towards areas of high contrast 21 Slide credit: Kristen Grauman

Gradient images and External energy at a point on the curve is: External energy for the whole curve: External image energy Kristen Grauman 22

Internal energy: intuition What are the underlying boundaries in this fragmented edge image? And in this one? Kristen Grauman 23

A priori, we want to favor smooth shapes, contours with low curvature, contours similar to a known shape, etc. to balance what is actually observed (i.e., in the gradient image). Internal energy: intuition Kristen Grauman 24

Internal energy For a continuous curve, a common internal energy term is the “bending energy”. At some point v(s) on the curve, this is: Tension, Elasticity Stiffness, Curvature Kristen Grauman 25

For our discrete representation, Internal energy for the whole curve: … Internal energy Note these are derivatives relative to position---not spatial image gradients. Why do these reflect tension and curvature? Kristen Grauman 26

Example: compare curvature (1,1) (2,2) (3,1) (2,5) Kristen Grauman 27

Penalizing elasticity Current elastic energy definition uses a discrete estimate of the derivative: What is the possible problem with this definition? Kristen Grauman 28

Penalizing elasticity Current elastic energy definition uses a discrete estimate of the derivative: where d is the average distance between pairs of points – updated at each iteration. Instead: Kristen Grauman 29

Dealing with missing data The preferences for low-curvature, smoothness help deal with missing data: [Figure from Kass et al. 1987] Illusory contours found! 30 Slide credit: Kristen Grauman

Extending the internal energy: capture shape prior If object is some smooth variation on a known shape, we can use a term that will penalize deviation from that shape: where are the points of the known shape. Fig from Y. Boykov 31 Slide credit: Kristen Grauman

Total energy: function of the weights 32 Slide credit: Kristen Grauman

large small medium e.g., weight controls the penalty for internal elasticity Fig from Y. Boykov Total energy: function of the weights 33 Slide credit: Kristen Grauman

Recap: deformable contour A simple elastic snake is defined by: –A set of n points, –An internal energy term (tension, bending, plus optional shape prior) –An external energy term (gradient-based) To use to segment an object: –Initialize in the vicinity of the object –Modify the points to minimize the total energy Kristen Grauman 34

Energy minimization Several algorithms have been proposed to fit deformable contours. We’ll look at two: –Greedy search –Dynamic programming (for 2d snakes) 35 Slide credit: Kristen Grauman

Energy minimization: greedy For each point, search window around it and move to where energy function is minimal –Typical window size, e.g., 5 x 5 pixels Stop when predefined number of points have not changed in last iteration, or after max number of iterations Note: –Convergence not guaranteed –Need decent initialization Kristen Grauman 36

Energy minimization Several algorithms have been proposed to fit deformable contours. We’ll look at two: –Greedy search –Dynamic programming (for 2d snakes) 37 Slide credit: Kristen Grauman

With this form of the energy function, we can minimize using dynamic programming, with the Viterbi algorithm. Iterate until optimal position for each point is the center of the box, i.e., the snake is optimal in the local search space constrained by boxes. [Amini, Weymouth, Jain, 1990] Fig from Y. Boykov Energy minimization: dynamic programming 38 Slide credit: Kristen Grauman

Energy minimization: dynamic programming Possible because snake energy can be rewritten as a sum of pair-wise interaction potentials: Or sum of triple-interaction potentials. 39 Slide credit: Kristen Grauman

Snake energy: pair-wise interactions where Re-writing the above with : Kristen Grauman 40

Main idea: determine optimal position (state) of predecessor, for each possible position of self. Then backtrack from best state for last vertex. states 1 2 … m vertices Complexity: vs. brute force search ____? Viterbi algorithm Example adapted from Y. Boykov 41 Slide credit: Kristen Grauman

With this form of the energy function, we can minimize using dynamic programming, with the Viterbi algorithm. Iterate until optimal position for each point is the center of the box, i.e., the snake is optimal in the local search space constrained by boxes. [Amini, Weymouth, Jain, 1990] Fig from Y. Boykov Energy minimization: dynamic programming 42 Slide credit: Kristen Grauman

DP can be applied to optimize an open ended snake For a closed snake, a “loop” is introduced into the total energy. Work around: 1)Fix v 1 and solve for rest. 2)Fix an intermediate node at its position found in (1), solve for rest. Energy minimization: dynamic programming 43 Slide credit: Kristen Grauman

Aspects we need to consider Representation of the contours Defining the energy functions –External –Internal Minimizing the energy function Extensions: –Tracking –Interactive segmentation 44 Slide credit: Kristen Grauman

Tracking via deformable contours 1.Use final contour/model extracted at frame t as an initial solution for frame t+1 2.Evolve initial contour to fit exact object boundary at frame t+1 3.Repeat, initializing with most recent frame. Tracking Heart Ventricles (multiple frames) Kristen Grauman 45

Visual Dynamics GroupVisual Dynamics Group, Dept. Engineering Science, University of Oxford. Traffic monitoring Human-computer interaction Animation Surveillance Computer assisted diagnosis in medical imaging Applications: Tracking via deformable contours Kristen Grauman 46

3D active contours Jörgen Ahlberg Kristen Grauman 47

May over-smooth the boundary Cannot follow topological changes of objects Limitations 48 Slide credit: Kristen Grauman

Limitations External energy: snake does not really “see” object boundaries in the image unless it gets very close to it. image gradients are large only directly on the boundary 49 Slide credit: Kristen Grauman

Distance transform External image can instead be taken from the distance transform of the edge image. original -gradient distance transform edges Value at (x,y) tells how far that position is from the nearest edge point (or other binary mage structure) >> help bwdist Kristen Grauman 50

Deformable contours: pros and cons Pros: Useful to track and fit non-rigid shapes Contour remains connected Possible to fill in “subjective” contours Flexibility in how energy function is defined, weighted. Cons: Must have decent initialization near true boundary, may get stuck in local minimum Parameters of energy function must be set well based on prior information Kristen Grauman 51

Summary Deformable shapes and active contours are useful for –Segmentation: fit or “snap” to boundary in image –Tracking: previous frame’s estimate serves to initialize the next Fitting active contours: –Define terms to encourage certain shapes, smoothness, low curvature, push/pulls, … –Use weights to control relative influence of each component cost –Can optimize 2d snakes with Viterbi algorithm. Image structure (esp. gradients) can act as attraction force for interactive segmentation methods. Kristen Grauman 52

Announcements PS2 out today –Regarding detecting circles Origin in MATLAB vs. math Consider trying code on a simple image first Project proposals due in a week –1 st October 2013 Slide credit: Devi Parikh 53

Questions? See you Thursday! 54 Slide credit: Devi Parikh