Finding nemo: Deformable object class modelling using curve matching

An image search for "clownfish" yields many photos of clownfish, each of a different individual of a different 3D shape in a different pose. Yet, to the human observer, this set of images contains enough information to infer the underlying 3D deformable object class. Our goal is to recover...

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Bibliographic Details
Published in2010 IEEE Computer Society Conference on Computer Vision and Pattern Recognition pp. 1720 - 1727
Main Authors Prasad, M, Fitzgibbon, A, Zisserman, A, Van Gool, L
Format Conference Proceeding
LanguageEnglish
Published IEEE 01.06.2010
Subjects
Active shape model
Deformable models
Dolphins
Humans
Image reconstruction
Information resources
Optimization methods
Shape measurement
Surface reconstruction
Surface texture
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Summary:An image search for "clownfish" yields many photos of clownfish, each of a different individual of a different 3D shape in a different pose. Yet, to the human observer, this set of images contains enough information to infer the underlying 3D deformable object class. Our goal is to recover such a deformable object class model directly from unordered images. For classes where feature-point correspondences can be found, this is a straightforward extension of non-rigid factorization, yielding a set of 3D basis shapes to explain the 2D data. However, when each image is of a different object instance, surface texture is generally unique to each individual, and does not give rise to usable image point correspondences. We overcome this sparsity using curve correspondences (crease-edge silhouettes or class-specific internal texture edges). Even rigid contour reconstruction is difficult due to the lack of reliable correspondences. We incorporate correspondence variation into the optimization, thereby extending contour-based reconstruction techniques to deformable object modelling. The notion of correspondence is extended to include mappings between 2D image curves and corresponding parts of the desired 3D object surface. Combined with class-specific priors, our method enables effective de-formable class reconstruction from unordered images, despite significant occlusion and the scarcity of shared 2D image features.
ISBN:1424469848
9781424469840
ISSN:1063-6919
1063-6919
DOI:10.1109/CVPR.2010.5539840