We propose GaussianObject, a framework to represent and render the 3D object with Gaussian splatting, that achieves high rendering quality with only 4 input images.
refresh.mp4
We first introduce techniques of visual hull and floater elimination which explicitly inject structure priors into the initial optimization process for helping build multi-view consistency, yielding a coarse 3D Gaussian representation. Then we construct a Gaussian repair model based on diffusion models to supplement the omitted object information, where Gaussians are further refined. We design a self-generating strategy to obtain image pairs for training the repair model. Our GaussianObject achives strong reconstruction results from only 4 views and significantly outperforms previous state-of-the-art methods.
- We initialize 3D Gaussians by constructing a visual hull with camera parameters and masked images, optimizing them with the
$\mathcal{L}_{\text{gs}}$ and refining through floater elimination. - We use a novel `leave-one-out' strategy and add 3D noise to Gaussians to generate corrupted Gaussian renderings. These renderings, paired with their corresponding reference images, facilitate the training of the Gaussian repair model employing
$\mathcal{L}_{\text{tune}}$ . - Once trained, the Gaussian repair model is frozen and used to correct views that need to be rectified. These views are identified through distance-aware sampling. The repaired images and reference images are used to further optimize 3D Gaussians with
$\mathcal{L}_{\text{rep}}$ and$\mathcal{L}_{\text{gs}}$ .
Sang Han provides a Colab script for GaussianObject in #9. Thanks for the contribution of the community! If you are experiencing issues with insufficient GPU VRAM, try this.
GaussianObject is tested with CUDA 11.7. If you are using a different version, you can choose to install nvidia/cuda in a local conda environment or modify the version of PyTorch in requirements.txt
.
The repository contains submodules. Please clone it with
git clone https://github.com/GaussianObject/GaussianObject.git --recursive
or update submodules in GaussianObject
directory with
git submodule update --init --recursive
You can try GaussianObject with the Mip-NeRF360 dataset and OmniObject3D dataset. The data can be downloaded in Google Drive.
The directory structure of the dataset should be
GaussianObject
├── data
│ ├── mip360
│ │ ├── bonsai
│ │ │ ├── images
│ │ │ ├── images_2
│ │ │ ├── images_4
│ │ │ ├── images_8
│ │ │ ├── masks
│ │ │ ├── sparse
│ │ │ ├── zoe_depth
│ │ │ ├── zoe_depth_colored
│ │ │ ├── sparse_4.txt
│ │ │ ├── sparse_6.txt
│ │ │ ├── sparse_9.txt
│ │ │ └── sparse_test.txt
│ │ ├── garden
│ │ └── kitchen
│ └── omni3d
└── ...
images
, images_2
, images_4
, images_8
and sparse
are from the original dataset. masks
is the object mask generated with segment-anything. zoe_depth
and zoe_depth_colored
are the depth maps and colored depth maps. sparse_4.txt
, sparse_6.txt
and sparse_9.txt
are train set image ids and sparse_test.txt
is the test set.
To test GaussianObject with your own dataset, you can manually prepare the dataset with the same directory structure. The depth maps and colored depth maps are generated with
python pred_monodepth.py -s <YOUR_DATA_DIR>
GaussianObject is tested with Python 3.10. All the required packages are listed in requirements.txt
. You can install them with
# setup pip packages
pip install -r requirements.txt
# setup submodules
pip install -e submodules/diff-gaussian-rasterization
pip install -e submodules/simple-knn
pip install -e submodules/pytorch3d
pip install -e submodules/minLoRA
pip install -e submodules/CLIP
Pretrained weights of Stable Diffusion v1.5 and ControlNet Tile need to be put in models/
following the instruction of ControlNet 1.1 with our given script
python download_hf_models.py
Taking the scene kitchen
from mip360
dataset as an example, GaussianObject generate the visual hull of it, train a coarse 3DGS representation, analyze the statistical regularity of the coarse model with leave-one-out strategy, fine-tune the Gaussian Repair Model with LoRA and repair the 3DGS representation step by step.
python visual_hull.py \
--sparse_id 4 \
--data_dir data/mip360/kitchen \
--reso 2 --not_vis
The visual hull is saved in data/mip360/kitchen/visual_hull_4.ply
.
python train_gs.py -s data/mip360/kitchen \
-m output/gs_init/kitchen \
-r 4 --sparse_view_num 4 --sh_degree 2 \
--init_pcd_name visual_hull_4 \
--white_background --random_background
You can render the coarse model it with
# render the test set
python render.py \
-m output/gs_init/kitchen \
--sparse_view_num 4 --sh_degree 2 \
--init_pcd_name visual_hull_4 \
--white_background --skip_all --skip_train
# render the path
python render.py \
-m output/gs_init/kitchen \
--sparse_view_num 4 --sh_degree 2 \
--init_pcd_name visual_hull_4 \
--white_background --render_path
The rendering results are saved in output/gs_init/kitchen/test/ours_10000
and output/gs_init/kitchen/render/ours_10000
.
python leave_one_out_stage1.py -s data/mip360/kitchen \
-m output/gs_init/kitchen_loo \
-r 4 --sparse_view_num 4 --sh_degree 2 \
--init_pcd_name visual_hull_4 \
--white_background --random_background
python leave_one_out_stage2.py -s data/mip360/kitchen \
-m output/gs_init/kitchen_loo \
-r 4 --sparse_view_num 4 --sh_degree 2 \
--init_pcd_name visual_hull_4 \
--white_background --random_background
python train_lora.py --exp_name controlnet_finetune/kitchen \
--prompt xxy5syt00 --sh_degree 2 --resolution 4 --sparse_num 4 \
--data_dir data/mip360/kitchen \
--gs_dir output/gs_init/kitchen \
--loo_dir output/gs_init/kitchen_loo \
--bg_white --sd_locked --train_lora --use_prompt_list \
--add_diffusion_lora --add_control_lora --add_clip_lora
python train_repair.py \
--config configs/gaussian-object.yaml \
--train --gpu 0 \
tag="kitchen" \
system.init_dreamer="output/gs_init/kitchen" \
system.exp_name="output/controlnet_finetune/kitchen" \
system.refresh_size=8 \
data.data_dir="data/mip360/kitchen" \
data.resolution=4 \
data.sparse_num=4 \
data.prompt="a photo of a xxy5syt00" \
data.refresh_size=8 \
system.sh_degree=2
The final 3DGS representation is saved in output/gaussian_object/kitchen/save/last.ply
. You can render it with
# render the test set
python render.py \
-m output/gs_init/kitchen \
--sparse_view_num 4 --sh_degree 2 \
--init_pcd_name visual_hull_4 \
--white_background --skip_all --skip_train \
--load_ply output/gaussian_object/kitchen/save/last.ply
# render the path
python render.py \
-m output/gs_init/kitchen \
--sparse_view_num 4 --sh_degree 2 \
--init_pcd_name visual_hull_4 \
--white_background --render_path \
--load_ply output/gaussian_object/kitchen/save/last.ply
The rendering results are saved in output/gs_init/kitchen/test/ours_None
and output/gs_init/kitchen/render/ours_None
.
Some code of GaussianObject is based on 3DGS, threestudio and ControlNet. Thanks for their great work!