Kerui Ren*, Lihan Jiang*, Tao Lu, Mulin Yu, Linning Xu, Zhangkai Ni, Bo Dai βοΈ
[2024.09.25] πWe propose Octree-AnyGS, a general anchor-based framework that supports explicit Gaussians (2D-GS, 3D-GS) and neural Gaussians (Scaffold-GS). Additionally, Octree-GS has been adapted to the aforementioned Gaussian primitives, enabling Level-of-Detail representation for large-scale scenes. This framework holds potential for application to other Gaussian-based methods, with relevant SIBR visualizations forthcoming.(https://github.com/city-super/Octree-AnyGS)
[2024.05.30] πWe update new mode (depth
, normal
, Gaussian distribution
and LOD Bias
) in the viewer for Octree-GS.
[2024.05.30] πWe release the checkpoints for the Mip-NeRF 360, Tanks&Temples, Deep Blending and MatrixCity Dataset.
[2024.04.08] πWe update the latest quantitative results on three datasets.
[2024.04.01] ππ The viewer for Octree-GS is available now.
[2024.04.01] We release the code.
Inspired by the Level-of-Detail (LOD) techniques, we introduce \modelname, featuring an LOD-structured 3D Gaussian approach supporting level-of-detail decomposition for scene representation that contributes to the final rendering results. Our model dynamically selects the appropriate level from the set of multi-resolution anchor points, ensuring consistent rendering performance with adaptive LOD adjustments while maintaining high-fidelity rendering results.
We tested on a server configured with Ubuntu 18.04, cuda 11.6 and gcc 9.4.0. Other similar configurations should also work, but we have not verified each one individually.
- Clone this repo:
git clone https://github.com/city-super/Octree-GS --recursive
cd Octree-GS
- Install dependencies
SET DISTUTILS_USE_SDK=1 # Windows only
conda env create --file environment.yml
conda activate octree_gs
First, create a data/
folder inside the project path by
mkdir data
The data structure will be organised as follows:
data/
βββ dataset_name
β βββ scene1/
β β βββ images
β β β βββ IMG_0.jpg
β β β βββ IMG_1.jpg
β β β βββ ...
β β βββ sparse/
β β βββ0/
β βββ scene2/
β β βββ images
β β β βββ IMG_0.jpg
β β β βββ IMG_1.jpg
β β β βββ ...
β β βββ sparse/
β β βββ0/
...
- The MipNeRF360 scenes are provided by the paper author here.
- The SfM data sets for Tanks&Temples and Deep Blending are hosted by 3D-Gaussian-Splatting here.
- The BungeeNeRF dataset is available in Google Drive/ηΎεΊ¦η½η[ζεη :4whv].
- The MatrixCity dataset can be downloaded from Hugging Face/Openxlab/ηΎεΊ¦η½η[ζεη :hqnn]. Point clouds used for training in our paper: pcd
Download and uncompress them into the
data/
folder.
For custom data, you should process the image sequences with Colmap to obtain the SfM points and camera poses. Then, place the results into data/
folder.
To train multiple scenes in parallel, we provide batch training scripts:
- MipNeRF360:
train_mipnerf360.sh
- Tanks&Temples:
train_tandt.sh
- Deep Blending:
train_db.sh
- BungeeNeRF:
train_bungeenerf.sh
- MatrixCity:
train_matrix_city.sh
run them with
bash train_xxx.sh
Notice 1: Make sure you have enough GPU cards and memories to run these scenes at the same time.
Notice 2: Each process occupies many cpu cores, which may slow down the training process. Set
torch.set_num_threads(32)
accordingly in thetrain.py
to alleviate it.
For training a single scene, modify the path and configurations in single_train.sh
accordingly and run it:
bash single_train.sh
- scene: scene name with a format of
dataset_name/scene_name/
orscene_name/
; - exp_name: user-defined experiment name;
- gpu: specify the GPU id to run the code. '-1' denotes using the most idle GPU.
- ratio: sampling interval of the SfM point cloud at initialization
- appearance_dim: dimensions of appearance embedding
- fork: proportion of subdivisions between LOD levels
- base_layer: the coarsest layer of the octree, corresponding to LOD 0, '<0' means scene-based setting
- visible_threshold: the threshold ratio of anchor points with low training frequency
- dist2level: the way floating-point values map to integers when estimating the LOD level
- update_ratio: the threshold ratio of anchor growing
- progressive: whether to use progressive learning
- levels: The number of LOD levels, '<0' means scene-based setting
- init_level: initial level of progressive learning
- extra_ratio: the threshold ratio of LOD bias
- extra_up: Increment of LOD bias per time
For these public datasets, the configurations of 'voxel_size' and 'fork' can refer to the above batch training script.
This script will store the log (with running-time code) into outputs/dataset_name/scene_name/exp_name/cur_time
automatically.
We've integrated the rendering and metrics calculation process into the training code. So, when completing training, the rendering results
, fps
and quality metrics
will be printed automatically. And the rendering results will be save in the log dir. Mind that the fps
is roughly estimated by
torch.cuda.synchronize();t_start=time.time()
rendering...
torch.cuda.synchronize();t_end=time.time()
which may differ somewhat from the original 3D-GS, but it does not affect the analysis.
Meanwhile, we keep the manual rendering function with a similar usage of the counterpart in 3D-GS, one can run it by
python render.py -m <path to trained model> # Generate renderings
python metrics.py -m <path to trained model> # Compute error metrics on renderings
scene | PSNR | SSIM | LPIPS | GS(k) | Mem(MB) |
---|---|---|---|---|---|
bicycle | 25.14 | 0.753 | 0.238 | 701 | 252.07 |
garden | 27.69 | 0.86 | 0.119 | 1344 | 272.67 |
stump | 26.61 | 0.763 | 0.265 | 467 | 145.50 |
room | 32.53 | 0.937 | 0.171 | 377 | 118.00 |
counter | 30.30 | 0.926 | 0.166 | 457 | 106.98 |
kitchen | 31.76 | 0.933 | 0.115 | 793 | 105.16 |
bonsai | 33.41 | 0.953 | 0.169 | 474 | 97.16 |
flowers | 21.47 | 0.598 | 0.342 | 726 | 238.57 |
treehill | 23.19 | 0.645 | 0.347 | 545 | 211.90 |
avg | 28.01 | 0.819 | 0.215 | 654 | 172.00 |
paper | 27.73 | 0.815 | 0.217 | 686 | 489.59 |
+0.28 | +0.004 | -0.002 | -4.66% | -64.87% |
scene | PSNR | SSIM | LPIPS | GS(k) | Mem(MB) |
---|---|---|---|---|---|
truck | 26.17 | 0.892 | 0.127 | 401 | 84.42 |
train | 23.04 | 0.837 | 0.184 | 446 | 84.45 |
avg | 24.61 | 0.865 | 0.156 | 424 | 84.44 |
paper | 24.52 | 0.866 | 0.153 | 481 | 410.48 |
+0.09 | -0.001 | +0.003 | -11.85% | -79.43% |
scene | PSNR | SSIM | LPIPS | GS(k) | Mem(MB) |
---|---|---|---|---|---|
drjohnson | 29.89 | 0.911 | 0.234 | 132 | 132.43 |
playroom | 31.08 | 0.914 | 0.246 | 93 | 53.94 |
avg | 30.49 | 0.913 | 0.240 | 113 | 93.19 |
paper | 30.41 | 0.913 | 0.238 | 144 | 254.87 |
+0.08 | - | +0.002 | -21.52% | -63.44% |
scene | PSNR | SSIM | LPIPS | GS(k) | Mem(GB) |
---|---|---|---|---|---|
Block_All | 26.99 | 0.833 | 0.257 | 453 | 2.36 |
paper | 26.41 | 0.814 | 0.282 | 665 | 3.70 |
+0.59 | +0.019 | -0.025 | -31.87% | -36.21% |
The viewers for Octree-GS is available now. Please follow the following format
<location>
|---point_cloud
| |---point_cloud.ply
| |---color_mlp.pt
| |---cov_mlp.pt
| |---opacity_mlp.pt
| (|---embedding_appearance.pt)
|---cameras.json
|---cfg_args
or
<location>
|---point_cloud
| |---iteration_{ITERATIONS}
| | |---point_cloud.ply
| | |---color_mlp.pt
| | |---cov_mlp.pt
| | |---opacity_mlp.pt
| | (|---embedding_appearance.pt)
|---cameras.json
|---cfg_args
- Kerui Ren: [email protected]
- Lihan Jiang: [email protected]
If you find our work helpful, please consider citing:
@article{ren2024octree,
title={Octree-gs: Towards consistent real-time rendering with lod-structured 3d gaussians},
author={Ren, Kerui and Jiang, Lihan and Lu, Tao and Yu, Mulin and Xu, Linning and Ni, Zhangkai and Dai, Bo},
journal={arXiv preprint arXiv:2403.17898},
year={2024}
}
Please follow the LICENSE of 3D-GS.
We thank all authors from 3D-GS and Scaffold-GS for presenting such an excellent work.