In this work, we propose an efficient iterative planar parameterization for disk topology shapes. The parameterization is used as a tool to regularize the mesh onto a square grid and encoded with vertex position. The resultant encoding is an image with rgb denoting xyz positions on the mesh.
The ICCV workshop paper can be found here. First part of this project deals with parameterization and second deals with learning of shapes from geometry images.
Code for Parameterization has been written in C++ and requires:
- CGAL Fork with Iterative Parameterization Implementation
- Boost
- OpenCV
Deep network code is based on Tensorflow and is tested on Ubuntu with:
- python (3.5.2)
- tensorflow-gpu (1.14)
- scikit-image (0.15.0)
- numpy (1.16.5)
- natsort
- tqdm
Code contains functionality for:
- slicing the mesh (--slice)
- Iterative Surface Parameterization with n iterations (--sPI n)
- Compute Geometry Image (of size im) from the parameterized representation (--m2G im)
- Remesh point cloud from Geometry Image (--G2o)
python based functionality which contains:
- generating curvature mask from normalGI
- tensorflow model
- docker image
- python scripts to train and test the model
If you find this project useful in your work, please consider citing:
@inproceedings{jain2019learning,
title={Learning to Reconstruct Symmetric Shapes using Planar Parameterization of 3D Surface},
author={Jain, Hardik and Wöllhaf, Manuel and Hellwich, Olaf},
booktitle={The IEEE International Conference on Computer Vision (ICCV) Workshops},
year={2019}
}