Exploring Differential Geometry in Neural Implicits

Tiago Novello [1], Guilherme Schardong [3], Luiz Schirmer [3], Vinícius da Silva [2], Hélio Lopes [2], Luiz Velho [1]
[1] Institute for Pure and Applied Mathematics (IMPA), [2] Pontifical Catholic University of Rio de Janeiro (PUC-Rio), [3] University of Coimbra (UC)

This is the official implementation of "Exploring Differential Geometry in Neural Implicits".

Getting started

Prerequisites

1. Anaconda, alternativelly you can use PyEnv and PyEnv-VirtualEnv on UNIX based/like systems
2. Git
3. Integrate Git Bash with conda (If on Windows)
4. MeshLab

Code organization

Most of the code is organized in the i3d package. Inside the corresponding folder, there are the following files:

• dataset.py - contains the sampling and data classes
• diff_operators.py - implementation of differential operators (gradient, hessian, jacobian, curvatures)
• loss_functions.py - contains loss functions for different experimental settings
• meshing.py - mesh creation through marching cubes
• model.py - network and layers implementations
• util.py - miscelaneous functions and utilities

Additionally, under the experiment_scripts folder, there are three scripts with experiments and other auxiliary code that is generally independent of the main code.

• comparison_analytic.py - comparison experiments of RBF, SIREN and our approach for analytic models of a sphere and torus
• comparison_ply.py - comparison experiments of RBF, SIREN and our approach for PLY models
• mesh2sdf_open3d_performance_test.py - performance test using SDF querying implemented in mesh2sdf and open3d. Not used in the paper, only testing if it was worth replacing the sampling code implemented using mesh2sdf with open3d.
• sdf_for_n_iters.py - Experiments with intermitent querying of off-surface points. Both to speed-up the training and test the influence of generating the off-surface points at each iteration.

In the tools folder, there are two scripts:

• estimate_mesh_curvatures.py: Given a trained model (pth) and the original mesh, we estimate the vertex curvatures using the trained model.
• reconstruct.py: Given a trained model (pth) reconstructs the mesh using marching cubes.

The main training script is located in the repository root

• train_sdf.py - main function and point-of-entry to our code

The parameters for our experiments are stored inside the yaml files in the experiments folder. Besides the experiments for each mesh, this folder has two template mostly identical files:

• default.yaml - parameters for uniform sampling
• default_curvature.yaml - parameters for curvature-based sampling

Note that for all curvature-based sampling experiments, the mesh must contain a curvature field. We expect it to be named "quality", following the meshlab convention and, in the PLY file, be the 7th data column.

Setup and sample run

1. Open a terminal (or Git Bash if using Windows)
2. Clone the repository: git clone [email protected]:dsilvavinicius/differential_geometry_in_neural_implicits.git i3d.
3. Enter project folder: cd i3d.
4. Create the environment and setup project dependencies:

conda env create -f environment.yml
conda activate i3d
pip install -e .

or, if using pyenv (with pyenv-virtualenv):

pyenv virtualenv 3.9.9 i3d
pyenv local i3d
pip install -r requirements.txt
pip install -e .

5. Download the datasets (available here) and extract them into the data folder of the repository
6. Train a network for the armadillo mesh:

python train_sdf.py data/armadillo_curvs.ply results/armadillo_curvs experiments/armadillo_curvature.yaml

7. The results will be stored in results/armadillo_curvs.
8. Convert the trained network back to a triangle mesh:

python tools/reconstruct.py results/armadillo_curvs/best.pth results/armadillo_curvs/best.ply

9. To visualize the output mesh by opening the output PLY using MeshLab:

meshlab results/armadillo_curvs/best.ply

End Result

If everything works, MeshLab should show the following image (or an image similar to it):

Linux

We tested the build steps stated above on Ubuntu 20.04. The prerequisites and setup remain the same, since all packages are available for both systems. We also provide a Makefile to cover the data download and network training and visualization (steps 5 through 9) above.

Running without graphical environments

If you are training your model in a remote server with no graphical environment, you will probably end up with the following error: pyglet.canvas.xlib.NoSuchDisplayException: Cannot connect to "None". This may happen during the SDF sampling step when iterating on a mesh. Basically, this means that pyglet needs a graphical display, which does not exist. You can work around this error by creating a virtual framebuffer, which can be done by prepending your python command with: xvfb-run -s "-screen 0 1400x900x24", as in:

xvfb-run -s "-screen 0 1400x900x24" python train_sdf.py experiments/armadillo_curvature.yaml

Naturally, you may adjust the resolution to fit your needs. This was tested on an Ubuntu Linux server and should work for other distributions. If using BSDs or other systems, your milleage may vary.

Citation

If you find our work useful in your research, please cite:

@article{novello:i3d:2022,
  title = {Exploring differential geometry in neural implicits},
  journal = {Computers & Graphics},
  volume = {108},
  pages = {49-60},
  year = {2022},
  issn = {0097-8493},
  doi = {https://doi.org/10.1016/j.cag.2022.09.003},
  url = {https://www.sciencedirect.com/science/article/pii/S0097849322001649},
  author = {Tiago Novello and Guilherme Schardong and Luiz Schirmer and Vinícius {da Silva} and Hélio Lopes and Luiz Velho},
  keywords = {Implicit surfaces, Neural Implicits, Neural Networks, Curvatures},
}

Contributors

Besides the paper authors, we list other contributors below. Thank you for helping make our code better!

DavidXu-JJ - Handling the U=W=0 case on diff_operators.principal_directions

Contact

If you have any questions, please feel free to email the authors, or open an issue.

Other examples

Principal curvatures and directions overlaid on the Armadillo.

Maximum curvature and corresponding direction on the Stanford Dragon.