Awesome
diffConv: Analyzing Irregular Point Clouds with an Irregular View
Standard spatial convolutions assume input data with a regular neighborhood structure. Existing methods typically generalize convolution to the irregular point cloud domain by fixing a regular "view" through e.g. a fixed neighborhood size, where the convolution kernel size remains the same for each point. However, since point clouds are not as structured as images, the fixed neighbor number gives an unfortunate inductive bias. We present a novel graph convolution named Difference Graph Convolution (diffConv), which does not rely on a regular view. diffConv operates on spatially-varying and density-dilated neighborhoods, which are further adapted by a learned masked attention mechanism. Experiments show that our model is very robust to the noise, obtaining state-of-the-art performance in 3D shape classification and scene understanding tasks, along with a faster inference speed.
Dependencies
- Python (tested on 3.7.11)
- PyTorch (tested on 1.9.0)
- CUDA (tested on 11.6)
- other packages: sklearn, h5py, open3d
- Install CUDA accelerated PointNet++ library under
models/pointnet2.
3D Object Shape Classification
ModelNet40
Prepare dataset
python3 data_prep.py --dataset=modelnet40
Train the model with default hyperparameters
python3 main_cls.py --exp_name=md40_cls --dataset=modelnet40
There are many hyperparameters to customize, call
python3 main_cls.py --help
for details.
Evaluate with our pretrained model
python3 main_cls.py --exp_name=md40_cls_eval --dataset=modelnet40 --eval=True --model_path=checkpoints/model_cls.pth
--model_path can be any trained parameters.
Evaluate model performance under noise
. eval_modelnet40noise.sh
Train model on resplited ModelNet40
python3 main_cls.py --exp_name=md40_resplit --dataset=modelnet40resplit
Note that everytime the dataset is randomly resplitted.
ModelNet40-C
Prepare dataset
Follow the official instruction, then move ModelNet40-C/data/modelnet40_c to data/modelnet40_c folder.
Evaluate with our pretrained model
. eval_modelnet40C.sh
ScanObjectNN
Prepare dataset
Download the dataset and unzip it at data/h5_files.
Train the model with default hyperparameters
python3 main_cls.py --exp_name=sonn_cls --dataset=scanobjectnn --bg=False
set --bg to True to train the model on the pointcloud with backgrounds.
Evaluation
Same as ModelNet40.
3D Scene Segmentation
NB: Please be aware that there could be an error on the Toronto3D segmentation, as reported in issues, causing the model to show constant (and anormal) IoU during training. I failed to reproduce the error when I ran the code from scratch, and thus not able to debug it. I am really sorry for this. My best guess is that this bug could be fixed by importing the anaconda environment from environment.yaml.
Toronto3D
Prepare dataset (may require torch 1.8.x)
Download the dataset and unzip it to data/Toronto_3D, then run
python3 data_prep.py --dataset=toronto3d
Train the model with default hyperparameters
python3 main_seg.py --exp_name=trt_seg
Evaluate with our pretrained model
python3 main_seg.py --exp_name=trt_seg --eval=True --model_path=checkpoints/model_seg.pth
3D Object Shape Segmentation
ShapeNetPart
Prepare dataset
python3 data_prep.py --dataset=shapenetpart
Train the model with default hyperparameters
python3 main_partseg.py --exp_name=spnetpt_seg
Evaluation
Same as other tasks.
Citation
Please cite this paper if you find this work helpful to your research,
@inproceedings{lin2021diffconv,
title={diffconv: Analyzing Irregular Point Clouds with an Irregular View},
author={Lin, Manxi and Feragen, Aasa},
booktitle={Proceedings of the European Conference on Computer Vision (ECCV)},
year={2022}
}
License
MIT License
Acknowledgements
Part of this codebase is borrowed from PointNet, DGCNN, dgcnn.pytorch, CurveNet, Pointnet2.ScanNet. Sincere appreciation to their works!