Learning Material-Aware Local Descriptors for 3D Shapes
Abstract
Material understanding is critical for design, geometric modeling, and analysis of functional objects. We enable material-aware 3D shape analysis by employing a projective convolutional neural network architecture to learn material- aware descriptors from view-based representations of 3D points for point-wise material classification or material- aware retrieval. Unfortunately, only a small fraction of shapes in 3D repositories are labeled with physical mate- rials, posing a challenge for learning methods. To address this challenge, we crowdsource a dataset of 3080 3D shapes with part-wise material labels. We focus on furniture models which exhibit interesting structure and material variabil- ity. In addition, we also contribute a high-quality expert- labeled benchmark of 115 shapes from Herman-Miller and IKEA for evaluation. We further apply a mesh-aware con- ditional random field, which incorporates rotational and reflective symmetries, to smooth our local material predic- tions across neighboring surface patches. We demonstrate the effectiveness of our learned descriptors for automatic texturing, material-aware retrieval, and physical simulation. The dataset and code will be publicly available.
Cite
@article{arxiv.1810.08729,
title = {Learning Material-Aware Local Descriptors for 3D Shapes},
author = {Hubert Lin and Melinos Averkiou and Evangelos Kalogerakis and Balazs Kovacs and Siddhant Ranade and Vladimir G. Kim and Siddhartha Chaudhuri and Kavita Bala},
journal= {arXiv preprint arXiv:1810.08729},
year = {2018}
}
Comments
3DV 2018