Yi-Ling Qiao*, Alexander Gao*, Ming C. Lin
Paper | Project Page | Video
We present a method for learning 3D geometry and physics parameters of a dynamic scene from only a monocular RGB video input.
This code has been tested on Ubuntu 20.04 with CUDA 11.3
Clone this repository and install dependencies. (Recommended to create a new conda env or pipenv.)
git clone https://github.com/gaoalexander/neuphysics.git
cd neuphysics
pip install -r requirements.txtDependencies (click to expand)
- torch==1.11.0 - opencv_python==4.5.5.64 - trimesh==3.9.8 - numpy==1.21.2 - pyhocon==0.3.57 - icecream==2.1.0 - tqdm==4.50.2 - scipy==1.7.0 - PyMCubes==0.1.2 - imageio=2.16.1 - scikit-image=0.19.2Download data and pretrained model weights on Google Drive.
Extract public_data and exp directories into the top-level neuphysics directory.
The data is organized as follows:
<case_name>
|-- cameras_xxx.npz # camera parameters
|-- sparse_points_interest.ply # contains scene ROI
|-- image
|-- 000.png # target image for each view
|-- 001.png
...
|-- mask
|-- 000.png # target mask each view (For unmasked setting, set all pixels as 255)
|-- 001.png
...
Here the cameras_xxx.npz follows the data format in IDR, where world_mat_xx denotes the world to image projection matrix, and scale_mat_xx denotes the normalization matrix.
- Training without mask
python run.py --mode train --conf ./confs/neuphysics_default.conf --case <case_name>- Extract surface from trained model for single frame/timestep
python run.py --mode validate_mesh --val_frame_idx <frame_index> --conf <config_file> --case <case_name> --is_continue # use latest checkpoint- Extract surface from trained model for entire motion sequence
python run.py --mode validate_mesh_sequence --conf <config_file> --case <case_name> --is_continue # use latest checkpointThe corresponding mesh can be found in exp/<case_name>/<exp_name>/meshes/<iter_steps>.ply.
- View interpolation
python run.py --mode interpolate_<img_idx_0>_<img_idx_1> --conf <config_file> --case <case_name> --is_continue # use latest checkpointThe corresponding image set of view interpolation can be found in exp/<case_name>/<exp_name>/render/.
- Train physics parameters Download the pretrained model weights on this Google Drive.
Install warp for differentiable simulation.
Run
python run.py --conf ./confs/womask.conf --case NeuS/custom/ball-motion3/preprocessed --mode train_physics_gravity_warp --is_continueWe are using warp because it runs on GPU and is much faster. We are also trying to provide the interface to taichi.
More information can be found in preprocess_custom_data.
If you find this repository helpful, please consider citing our paper as well as others that our work built upon:
@inproceedings{qiao2022neuphysics,
author = {Qiao, Yi-Ling and Gao, Alexander and Lin, Ming C.},
title = {NeuPhysics: Editable Neural Geometry and Physics from Monocular Videos},
booktitle = {Conference on Neural Information Processing Systems (NeurIPS)},
year = {2022},
}
@article{wang2021neus,
title={NeuS: Learning Neural Implicit Surfaces by Volume Rendering for Multi-view Reconstruction},
author={Peng Wang and Lingjie Liu and Yuan Liu and Christian Theobalt and Taku Komura and Wenping Wang},
journal={NeurIPS},
year={2021}
}
@inproceedings{tretschk2021nonrigid,
title = {Non-Rigid Neural Radiance Fields: Reconstruction and Novel View Synthesis of a Dynamic Scene From Monocular Video},
author = {Tretschk, Edgar and Tewari, Ayush and Golyanik, Vladislav and Zollh\"{o}fer, Michael and Lassner, Christoph and Theobalt, Christian},
booktitle = {{IEEE} International Conference on Computer Vision ({ICCV})},
year = {2021},
}
@article{du2021_diffpd,
author = {Du, Tao and Wu, Kui and Ma, Pingchuan and Wah, Sebastien and Spielberg, Andrew and Rus, Daniela and Matusik, Wojciech},
title = {DiffPD: Differentiable Projective Dynamics},
year = {2021},
journal = {ACM Trans. Graph.},
}
Our code borrows from NeuS and NonRigid NeRF. Additionally, some code snippets are borrowed from IDR and NeRF-pytorch.
Thank you to the authors of these projects for their great work.