This repository contains a concise and extensible implementation of NeRF and NeuS for neural surface reconstruction based on Instant-NGP and the Pytorch-Lightning framework. Training on a NeRF-Synthetic scene takes ~5min for NeRF and ~10min for NeuS on a single RTX3090.
NeRF in 5min | NeuS in 10 min | |
---|---|---|
Rendering | ||
Mesh |
This repository aims to provide a highly efficient while customizable boilerplate for research projects based on NeRF or NeuS.
- acceleration techniques from Instant-NGP: multiresolution hash encoding and fully fused networks by tiny-cuda-nn, occupancy grid pruning and rendering by nerfacc
- out-of-the-box multi-GPU and mixed precision training by PyTorch-Lightning
- hierarchical project layout that is designed to be easily customized and extended, flexible experiment configuration by OmegaConf
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- 06/03/2023: Add an implementation of Neuralangelo. See here for details.
- 03/31/2023: NeuS model now supports background modeling. You could try on the DTU dataset provided by NeuS or IDR following the instruction here.
- 02/11/2023: NeRF model now supports unbounded 360 scenes with learned background. You could try on MipNeRF 360 data following the COLMAP configuration.
Note:
- To utilize multiresolution hash encoding or fully fused networks provided by tiny-cuda-nn, you should have least an RTX 2080Ti, see https://github.com/NVlabs/tiny-cuda-nn#requirements for more details.
- Multi-GPU training is currently not supported on Windows (see #4).
- Install PyTorch>=1.10 here based the package management tool you used and your cuda version (older PyTorch versions may work but have not been tested)
- Install tiny-cuda-nn PyTorch extension:
pip install git+https://github.com/NVlabs/tiny-cuda-nn/#subdirectory=bindings/torch
pip install -r requirements.txt
Download the NeRF-Synthetic data here and put it under load/
. The file structure should be like load/nerf_synthetic/lego
.
Run the launch script with --train
, specifying the config file, the GPU(s) to be used (GPU 0 will be used by default), and the scene name:
# train NeRF
python launch.py --config configs/nerf-blender.yaml --gpu 0 --train dataset.scene=lego tag=example
# train NeuS with mask
python launch.py --config configs/neus-blender.yaml --gpu 0 --train dataset.scene=lego tag=example
# train NeuS without mask
python launch.py --config configs/neus-blender.yaml --gpu 0 --train dataset.scene=lego tag=example system.loss.lambda_mask=0.0
The code snapshots, checkpoints and experiment outputs are saved to exp/[name]/[tag]@[timestamp]
, and tensorboard logs can be found at runs/[name]/[tag]@[timestamp]
. You can change any configuration in the YAML file by specifying arguments without --
, for example:
python launch.py --config configs/nerf-blender.yaml --gpu 0 --train dataset.scene=lego tag=iter50k seed=0 trainer.max_steps=50000
Download preprocessed DTU data provided by NeuS or IDR. In the provided config files we assume using NeuS DTU data. If you are using IDR DTU data, please set dataset.cameras_file=cameras.npz
. You may also need to adjust dataset.root_dir
to point to your downloaded data location.
# train NeuS on DTU without mask
python launch.py --config configs/neus-dtu.yaml --gpu 0 --train
# train NeuS on DTU with mask
python launch.py --config configs/neus-dtu-wmask.yaml --gpu 0 --train
# train NeuS on DTU with mask using tricks from Neuralangelo (experimental)
python launch.py --config configs/neuralangelo-dtu-wmask.yaml --gpu 0 --train
Notes:
- PSNR in the testing stage is meaningless, as we simply compare to pure white images in testing.
- The results of Neuralangelo can't reach those in the original paper. Some potential improvements: more iterations; larger
system.geometry.xyz_encoding_config.update_steps
; largersystem.geometry.xyz_encoding_config.n_features_per_level
; largersystem.geometry.xyz_encoding_config.log2_hashmap_size
; adopting curvature loss.
To get COLMAP data from custom images, you should have COLMAP installed (see here for installation instructions). Then put your images in the images/
folder, and run scripts/imgs2poses.py
specifying the path containing the images/
folder. For example:
python scripts/imgs2poses.py ./load/bmvs_dog # images are in ./load/bmvs_dog/images
Existing data following this file structure also works as long as images are store in images/
and there is a sparse/
folder for the COLMAP output, for example the data provided by MipNeRF 360. An optional masks/
folder could be provided for object mask supervision. To train on COLMAP data, please refer to the example config files config/*-colmap.yaml
. Some notes:
- Adapt the
root_dir
andimg_wh
(orimg_downscale
) option in the config file to your data; - The scene is normalized so that cameras have a minimum distance
1.0
to the center of the scene. Settingmodel.radius=1.0
works in most cases. If not, try setting a smaller radius that wraps tightly to your foreground object. - There are three choices to determine the scene center:
dataset.center_est_method=camera
uses the center of all camera positions as the scene center;dataset.center_est_method=lookat
assumes the cameras are looking at the same point and calculates an approximate look-at point as the scene center;dataset.center_est_method=point
uses the center of all points (reconstructed by COLMAP) that are bounded by cameras as the scene center. Please choose an appropriate method according to your capture. - PSNR in the testing stage is meaningless, as we simply compare to pure white images in testing.
The training procedure are by default followed by testing, which computes metrics on test data, generates animations and exports the geometry as triangular meshes. If you want to do testing alone, just resume the pretrained model and replace --train
with --test
, for example:
python launch.py --config path/to/your/exp/config/parsed.yaml --resume path/to/your/exp/ckpt/epoch=0-step=20000.ckpt --gpu 0 --test
All experiments are conducted on a single NVIDIA RTX3090.
PSNR | Chair | Drums | Ficus | Hotdog | Lego | Materials | Mic | Ship | Avg. |
---|---|---|---|---|---|---|---|---|---|
NeRF Paper | 33.00 | 25.01 | 30.13 | 36.18 | 32.54 | 29.62 | 32.91 | 28.65 | 31.01 |
NeRF Ours (20k) | 34.80 | 26.04 | 33.89 | 37.42 | 35.33 | 29.46 | 35.22 | 31.17 | 32.92 |
NeuS Ours (20k, with masks) | 34.04 | 25.26 | 32.47 | 35.94 | 33.78 | 27.67 | 33.43 | 29.50 | 31.51 |
Training Time (mm:ss) | Chair | Drums | Ficus | Hotdog | Lego | Materials | Mic | Ship | Avg. |
---|---|---|---|---|---|---|---|---|---|
NeRF Ours (20k) | 04:34 | 04:35 | 04:18 | 04:46 | 04:39 | 04:35 | 04:26 | 05:41 | 04:42 |
NeuS Ours (20k, with masks) | 11:25 | 10:34 | 09:51 | 12:11 | 11:37 | 11:46 | 09:59 | 16:25 | 11:44 |
- [✅] Support more dataset formats, like COLMAP outputs and DTU
- [✅] Support simple background model
- Support GUI training and interaction
- More illustrations about the framework
- ngp_pl: Great Instant-NGP implementation in PyTorch-Lightning! Background model and GUI supported.
- Instant-NSR: NeuS implementation using multiresolution hash encoding.
If you find this codebase useful, please consider citing:
@misc{instant-nsr-pl,
Author = {Yuan-Chen Guo},
Year = {2022},
Note = {https://github.com/bennyguo/instant-nsr-pl},
Title = {Instant Neural Surface Reconstruction}
}