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Formation et Analyse d’Images Session 8
Daniela Hall 14 November 2005
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Course Overview Session 1 (19/09/05) Session 2 (26/09/05)
Human vision Homogenous coordinates Camera models Session 2 (26/09/05) Tensor notation Image transformations Homography computation Session 3 (3/10/05) Camera calibration Reflection models Color spaces Session 4 (10/10/05) Pixel based image analysis 17/10/05 course is replaced by Modelisation surfacique
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Course overview Session 5 + 6 (24/10/05) 9:45 – 12:45
Contrast description Hough transform Session 7 (7/11/05) Kalman filter Session 8 (14/11/05) Tracking of regions, pixels, and lines Session 9 (21/11/05) Gaussian filter operators Session 10 (5/12/05) Scale Space Session 11 (12/12/05) Stereo vision Epipolar geometry Session 12 (16/01/06): exercises and questions
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Session overview Tracking of objects
Architecture of the robust tracker Tracking using Kalman filter Tracking using CONDENSATION
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Robust tracking of objects
List of predictions Predict Detection List of targets Measurements Correct Trigger regions New targets Detection
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Tracking system Tracking system: detects position of targets at each time instant (using i.e. background differencing)
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Tracking system Supervisor Target observation module Detection module
calls image acquisition, target observation and detection in a cycle Target observation module ensures robust tracking by prediction of target positions using a Kalman filter Detection module verifies the predicted positions by measuring detection energy within the search region given by the Kalman filter creates new targets by evaluating detection energy within trigger regions Parameters noise threshold, detection energy threshold, parameters for splitting and merging
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Detection by background differencing
I=(IR,IG,IB) image, B=(BR,BG,BB) background Compute a binary difference image Id, where all pixels that have a difference diff larger than the noise threshold w are set to one. Then we compute the connected components of Id to detect the pixels that belong to a target. For each target, we compute mean and covariance of its pixels. The covariance is transformed to width and height of the bounding box and orientation of the target.
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Real-time target detection
Computing connected components for an image is computationally expensive. Idea: Restrict search of targets to a small number of search regions. These regions are: Entry regions marked by the user Search region obtained from the Kalman filter that predicts the next most likely position of a current target.
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Background adaption to increase robustness of detection
In long-term tracking, illumination of a scene changes. Image differencing with a static background causes lots of false detections. The background is updated regularily by t time, α=0.1 background adaption parameter Background adaption allows that the background incorporates slow illumination changes.
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Example Detection module Parameters: detection energy threshold
energy threshold too high: targets are missed or targets are split energy threshold too low: false detections Problem: energy threshold depends on illumination and target appearance
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Session overview Tracking of objects
Architecture of the robust tracker Tracking using Kalman filter Tracking using CONDENSATION
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Tracking Targets are represented by position (x,y) and covariance.
A first order Kalman filter is used to predict the position of the target in the next frame. The Kalman filter provides a ROI where to look for the target. ROI is computed from the a posteriori estimate xk and from the a posteriori error covariance Pk
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Example
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Example: Tracking bouncing ball
Specifications: constant background colored ball Problems: noisy observations motion blur rapid motion changes Thanks to B. Fisher UEdin for providing slides and figures of this example.
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Ball physical model Position zk = (x, y)
Position update zk = zk-1 + vk-1Δt Velocity update vk = vk-1+ak-1Δt Acceleration (gravity down) ak=(0,g)T
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Robust tracking of objects
Measurement State vector State equation Prediction State control
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Robust Tracking of objects
Measurement noise error covariance Temporal matrix Process noise error covariance a affects the computation speed (large a increases uncertainty and therefore the search regions)
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Kalman filter successes
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Kalman filter failures
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Kalman filter analysis
smoothes noisy observations dynamic model fails at bounce and stop could estimate ball radius could plot a boundary of 95% likelihood of ball position (the boundary would grow when the fit is bad).
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Session overview Tracking of objects
Architecture of the robust tracker Tracking using Kalman filter Tracking using CONDENSATION
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Tracking by CONDENSATION
CONDENSATION: Conditional Density Propagation. Also known as Particle Filtering. Ref: M.Isard and A. Blake: CONDENSATION for visual tracking, Int Journal of Computer Vision, 29(1),1998.
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CONDENSATION tracking
Keeps multiple hypotheses updates using new data selects hypotheses probabilistically copes with very noisy data and process state changes tunable computation load (by choosing number of particles).
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CONDENSATION algorithm
Given a set of N hypotheses at time k Hk={x1,k, ... , xN,k} with associated probabilities {p(x1,k), ..., p(xN,k)} Repeat N times to generate Hk+1 1. randomly select a hypothesis xu,k from Hk with p(xu,k) 2. generate a new state vector sk from a distribution centered at xu,k 3. get new state vector using dynamic model xk+1=f(sk) and kalman filter. 4. evaluate probability p(zk+1|xk+1) of observed data zk+1 given state xk 5. use bayes rule to get p(xk+1|zk+1)
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CONDENSATION algorithm
Figure from book Isard, Blake: Active Contours
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Why does condensation tracking work?
many slightly different hypotheses suggests that maybe we find one that fits better. dynamic model allows to switch between different motion models Motion models of bouncing ball: bounce, freefall, stop sampling by probability weeds out bad hypotheses
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Tracking of bouncing ball
Select 100 hypotheses xk with probabilities p(xk) use estimated covariance P() to create state samples sk define a situation switching model
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Tracking of bouncing ball
If in STOP situation: y'=0 If in BOUNCE: x'=-0.7x', also add some random y' motion, y'=y'+r. If in FREEFALL: use freefall motion model. y'=gΔt and x'=x'+r then use Kalman filter for predicting ^xk 4. estimate hypothesis goodness by 1/||Hxk – zk||2 p(xk) is estimated from the goodness by normalization.
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Example of sampling effects
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Kalman filter failures fixed
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Comparison Kalman vs condensation
assumes Gaussian motion model. Easy to parametrize. Fast. Condensation: can track objects with non-gaussian motion. very good for multi-modal motion models simple algorithm reasonably fast
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