Texture, Contours and Regions: Cue Integration in Image

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Transcript Texture, Contours and Regions: Cue Integration in Image

Computational Vision
Jitendra Malik
University of California at Berkeley
Taxonomy of Vision Problems
• Reconstruction:
– estimate parameters of external 3D world.
• Visual Control:
– visually guided locomotion and manipulation.
• Segmentation:
– partition I(x,y,t) into subsets of separate objects.
• Recognition:
– classes: face vs. non-face,
– activities: gesture, expression.
Reconstruction
• Computer graphics is the forward problem:
given scene geometry, reflectances and
lighting, synthesize an image.
• Computer vision must address the inverse
problem: given an image/multiple images,
reconstruct the scene geometry, reflectacnes
and illumination.
Recovering geometry
• Historical roots in photogrammetry and
analysis of 3D cues in human vision
• Single images adequate given knowledge of
object class
• Multiple images make the problem easier,
but not trivial as corresponding points must
be identified.
Arc de
Triomphe
Taj Mahal
modeled from
one photograph
by G. Borshukov
Recovered Campus Model
Campanile + 40 Buildings (Debevec et al)
Inverse Global Illumination (Yu et al)
Reflectance
Properties
Radiance
Maps
Geometry
Light
Sources
Real vs. Synthetic
Real vs. Synthetic
Challenges in Reconstruction
• Finding correspondences automatically
• Optimal estimation of structure from n
views under perspective projection
• Models of reflectance and texture for
natural materials and objects
Control
• Visual feedback signal for control of
manipulation tasks such as grasping,
moving and assembly
• Visual feedback for guiding locomotion
– Obstacle avoidance for a moving robot
– Lateral and longitudinal control of driving
Challenges in control
• Delay in feedback loop due to visual
processing
• Hierarchies in sensory motor control
– Open loop or closed loop
– Discrete planning or continuous control
Image Segmentation
Boundaries of image regions defined
by a number of attributes
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Brightness/color
Texture
Motion
Stereoscopic depth
Familiar configuration
Approaches
• Fitting a piecewise smooth surface to the
image e.g. Mumford and Shah
• Probabilistic Inference using Markov
Random Field model of image e.g. Geman
and Geman
• Graph partitioning using spectral techniques
e.g. Shi and Malik
Image Segmentation as Graph Partitioning
Build a weighted graph G=(V,E) from image
V: image pixels
E: connections between
pairs of nearby pixels
Wij : probabilit y that i &j
belong to the same
region
Partition graph so that similarity within group is large and
similarity between groups is small -- Normalized Cuts
[Shi&Malik 97]
Temporal Segmentation: Tracking
Challenges in Segmentation
• Interaction of multiple cues
• Local measurements to global percepts
• Interplay of image-driven and object model
driven processing
Recognition
• Possible for both instances or object classes (Mona
Lisa vs. faces or Beetle vs. cars)
• Tolerant to changes in pose and illumination, and
occlusion
Recognition of Gait and Gesture
run
measurement recognition
animation
Challenges in recognition
• Unified framework for segmentation and
recognition
• Representing shape variability in a category
• Interplay of discriminative vs generative
models
Core disciplines
• Geometry
– Differential geometry
– Projective geometry
• Probability and Statistics
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Reconstruction = estimation
Control = decision theory
Segmentation = clustering
Recognition = classification