Shapeme histogram projection and matching for partial object recognition

Histograms of shape signature or prototypical shapes, called shapemes, have been used effectively in previous work for 2D/3D shape matching and recognition. We extend the idea of shapeme histogram to recognize partially observed query objects from a database of complete model objects. We propose rep...

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Bibliographic Details
Published in:IEEE transactions on pattern analysis and machine intelligence 2006-04, Vol.28 (4), p.568-577
Main Authors: Ying Shan, Sawhney, H.S., Matei, B., Kumar, R.
Format: Article
Language:English
Subjects:
Algorithms
Applied sciences
Artificial Intelligence
Bayesian analysis
Bayesian methods
Computer science
control theory
systems
Computer Simulation
Constraint optimization
Exact sciences and technology
feature saliency
Gibbs sampling
Histograms
Image Enhancement - methods
Image Interpretation, Computer-Assisted - methods
Imaging, Three-Dimensional - methods
Information Storage and Retrieval - methods
Information systems. Data bases
Layout
Matching
Memory organisation. Data processing
Models, Biological
Models, Statistical
Object recognition
Pattern Recognition, Automated - methods
Pattern recognition. Digital image processing. Computational geometry
Projection
Prototypes
Query processing
Recognition
Reproducibility of Results
Sampling methods
Sensitivity and Specificity
Shape measurement
Shapeme histogram
Software
Spatial databases
spin image
Studies
Subspace constraints
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Summary:Histograms of shape signature or prototypical shapes, called shapemes, have been used effectively in previous work for 2D/3D shape matching and recognition. We extend the idea of shapeme histogram to recognize partially observed query objects from a database of complete model objects. We propose representing each model object as a collection of shapeme histograms and match the query histogram to this representation in two steps: 1) compute a constrained projection of the query histogram onto the subspace spanned by all the shapeme histograms of the model and 2) compute a match measure between the query histogram and the projection. The first step is formulated as a constrained optimization problem that is solved by a sampling algorithm. The second step is formulated under a Bayesian framework, where an implicit feature selection process is conducted to improve the discrimination capability of shapeme histograms. Results of matching partially viewed range objects with a 243 model database demonstrate better performance than the original shapeme histogram matching algorithm and other approaches.
ISSN:0162-8828
1939-3539
DOI:10.1109/TPAMI.2006.83