From Deformations to Parts: Motion-Based Segmentation of 3D Objects
Abstract
We develop a method for discovering the parts of an articulated object from aligned meshes capturing various three-dimensional (3D) poses. We adapt the distance dependent Chinese restaurant process (ddCRP) to allow nonparametric discovery of a potentially unbounded number of parts, while simultaneously guaranteeing a spatially connected segmentation. To allow analysis of datasets in which object instances have varying shapes, we model part variability across poses via affine transformations. By placing a matrix normal-inverse-Wishart prior on these affine transformations, we develop a ddCRP Gibbs sampler which tractably marginalizes over transformation uncertainty. Analyzing a dataset of humans captured in dozens of poses, we infer parts which provide quantitatively better motion predictions than conventional clustering methods.
Cite
Text
Ghosh et al. "From Deformations to Parts: Motion-Based Segmentation of 3D Objects." Neural Information Processing Systems, 2012.Markdown
[Ghosh et al. "From Deformations to Parts: Motion-Based Segmentation of 3D Objects." Neural Information Processing Systems, 2012.](https://mlanthology.org/neurips/2012/ghosh2012neurips-deformations/)BibTeX
@inproceedings{ghosh2012neurips-deformations,
title = {{From Deformations to Parts: Motion-Based Segmentation of 3D Objects}},
author = {Ghosh, Soumya and Loper, Matthew and Sudderth, Erik B. and Black, Michael J.},
booktitle = {Neural Information Processing Systems},
year = {2012},
pages = {1997-2005},
url = {https://mlanthology.org/neurips/2012/ghosh2012neurips-deformations/}
}