This repo provides code and models for GDRNPP_BOP2022, winner (most of the awards) of the BOP Challenge 2022 at ECCV'22 [slides].
Download the 6D pose datasets from the
BOP website and
VOC 2012
for background images.
Please also download the test_bboxes
from
here OneDrive (password: groupji) or BaiDuYunPan(password: vp58).
The structure of datasets
folder should look like below:
datasets/
├── BOP_DATASETS # https://bop.felk.cvut.cz/datasets/
├──tudl
├──lmo
├──ycbv
├──icbin
├──hb
├──itodd
└──tless
└──VOCdevkit
Download the trained models at Onedrive (password: groupji) or BaiDuYunPan(password: 10t3) and put them in the folder ./output
.
- Ubuntu 18.04/20.04, CUDA 10.1/10.2/11.6, python >= 3.7, PyTorch >= 1.9, torchvision
- Install
detectron2
from source sh scripts/install_deps.sh
- Compile the cpp extensions for
-
farthest points sampling (fps)
-
flow
-
uncertainty pnp
-
ransac_voting
-
chamfer distance
-
egl renderer
sh ./scripts/compile_all.sh
We adopt yolox as the detection method. We used stronger data augmentation and ranger optimizer.
Download the pretrained model at Onedrive (password: groupji) or BaiDuYunPan(password: aw68) and put it in the folder pretrained_models/yolox
. Then use the following command:
./det/yolox/tools/train_yolox.sh <config_path> <gpu_ids> (other args)
./det/yolox/tools/test_yolox.sh <config_path> <gpu_ids> <ckpt_path> (other args)
The difference between this repo and GDR-Net (CVPR2021) mainly including:
- Domain Randomization: We used stronger domain randomization operations than the conference version during training.
- Network Architecture: We used a more powerful backbone Convnext rather than resnet-34, and two mask heads for predicting amodal mask and visible mask separately.
- Other training details, such as learning rate, weight decay, visible threshold, and bounding box type.
./core/gdrn_modeling/train_gdrn.sh <config_path> <gpu_ids> (other args)
For example:
./core/gdrn_modeling/train_gdrn.sh configs/gdrn/ycbv/convnext_a6_AugCosyAAEGray_BG05_mlL1_DMask_amodalClipBox_classAware_ycbv.py 0
./core/gdrn_modeling/test_gdrn.sh <config_path> <gpu_ids> <ckpt_path> (other args)
For example:
./core/gdrn_modeling/test_gdrn.sh configs/gdrn/ycbv/convnext_a6_AugCosyAAEGray_BG05_mlL1_DMask_amodalClipBox_classAware_ycbv.py 0 output/gdrn/ycbv/convnext_a6_AugCosyAAEGray_BG05_mlL1_DMask_amodalClipBox_classAware_ycbv/model_final_wo_optim.pth
We utilize depth information to further refine the estimated pose. We provide two types of refinement: fast refinement and iterative refinement.
For fast refinement, we compare the rendered object depth and the observed depth to refine translation. Run
./core/gdrn_modeling/test_gdrn_depth_refine.sh <config_path> <gpu_ids> <ckpt_path> (other args)
For iterative refinement, please checkout to the pose_refine branch for details.
If you use GDRNPP in your research, please use the following BibTeX entries.
@misc{liu2022gdrnpp_bop,
author = {Xingyu Liu and Ruida Zhang and Chenyangguang Zhang and
Bowen Fu and Jiwen Tang and Xiquan Liang and Jingyi Tang and
Xiaotian Cheng and Yukang Zhang and Gu Wang and Xiangyang Ji},
title = {GDRNPP},
howpublished = {\url{https://github.com/shanice-l/gdrnpp_bop2022}},
year = {2022}
}
@InProceedings{Wang_2021_GDRN,
title = {{GDR-Net}: Geometry-Guided Direct Regression Network for Monocular 6D Object Pose Estimation},
author = {Wang, Gu and Manhardt, Fabian and Tombari, Federico and Ji, Xiangyang},
booktitle = {IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR)},
month = {June},
year = {2021},
pages = {16611-16621}
}