English

DEMEA: Deep Mesh Autoencoders for Non-Rigidly Deforming Objects

Computer Vision and Pattern Recognition 2020-08-05 v2 Graphics

Abstract

Mesh autoencoders are commonly used for dimensionality reduction, sampling and mesh modeling. We propose a general-purpose DEep MEsh Autoencoder (DEMEA) which adds a novel embedded deformation layer to a graph-convolutional mesh autoencoder. The embedded deformation layer (EDL) is a differentiable deformable geometric proxy which explicitly models point displacements of non-rigid deformations in a lower dimensional space and serves as a local rigidity regularizer. DEMEA decouples the parameterization of the deformation from the final mesh resolution since the deformation is defined over a lower dimensional embedded deformation graph. We perform a large-scale study on four different datasets of deformable objects. Reasoning about the local rigidity of meshes using EDL allows us to achieve higher-quality results for highly deformable objects, compared to directly regressing vertex positions. We demonstrate multiple applications of DEMEA, including non-rigid 3D reconstruction from depth and shading cues, non-rigid surface tracking, as well as the transfer of deformations over different meshes.

Keywords

Cite

@article{arxiv.1905.10290,
  title  = {DEMEA: Deep Mesh Autoencoders for Non-Rigidly Deforming Objects},
  author = {Edgar Tretschk and Ayush Tewari and Michael Zollhöfer and Vladislav Golyanik and Christian Theobalt},
  journal= {arXiv preprint arXiv:1905.10290},
  year   = {2020}
}

Comments

27 pages, including supplementary material

R2 v1 2026-06-23T09:22:35.371Z