DocumentCode
3426162
Title
Flattening Supervoxel Hierarchies by the Uniform Entropy Slice
Author
Chenliang Xu ; Whitt, Spencer ; Corso, Jason J.
Author_Institution
Comput. Sci. & Eng., SUNY at Buffalo, Buffalo, NY, USA
fYear
2013
fDate
1-8 Dec. 2013
Firstpage
2240
Lastpage
2247
Abstract
Supervoxel hierarchies provide a rich multiscale decomposition of a given video suitable for subsequent processing in video analysis. The hierarchies are typically computed by an unsupervised process that is susceptible to under-segmentation at coarse levels and over-segmentation at fine levels, which make it a challenge to adopt the hierarchies for later use. In this paper, we propose the first method to overcome this limitation and flatten the hierarchy into a single segmentation. Our method, called the uniform entropy slice, seeks a selection of supervoxels that balances the relative level of information in the selected supervoxels based on some post hoc feature criterion such as object-ness. For example, with this criterion, in regions nearby objects, our method prefers finer supervoxels to capture the local details, but in regions away from any objects we prefer coarser supervoxels. We formulate the uniform entropy slice as a binary quadratic program and implement four different feature criteria, both unsupervised and supervised, to drive the flattening. Although we apply it only to supervoxel hierarchies in this paper, our method is generally applicable to segmentation tree hierarchies. Our experiments demonstrate both strong qualitative performance and superior quantitative performance to state of the art baselines on benchmark internet videos.
Keywords
entropy; image segmentation; quadratic programming; trees (mathematics); video signal processing; benchmark Internet videos; binary quadratic program; coarse level; entropy slice uniformity; fine level; hoc feature criterion; segmentation tree hierarchy; supervised feature criteria; supervoxel hierarchy flattening; supervoxel selection; unsupervised feature criteria; unsupervised process; video analysis; video multiscale decomposition; Benchmark testing; Entropy; Image coding; Image segmentation; Measurement; Motion segmentation; Vectors;
fLanguage
English
Publisher
ieee
Conference_Titel
Computer Vision (ICCV), 2013 IEEE International Conference on
Conference_Location
Sydney, NSW
ISSN
1550-5499
Type
conf
DOI
10.1109/ICCV.2013.279
Filename
6751389
Link To Document