Awesome
Point-GNN
This repository contains a reference implementation of our Point-GNN: Graph Neural Network for 3D Object Detection in a Point Cloud, CVPR 2020.
If you find this code useful in your research, please consider citing our work:
@InProceedings{Point-GNN,
author = {Shi, Weijing and Rajkumar, Ragunathan (Raj)},
title = {Point-GNN: Graph Neural Network for 3D Object Detection in a Point Cloud},
booktitle = {The IEEE Conference on Computer Vision and Pattern Recognition (CVPR)},
month = {June},
year = {2020}
}
Getting Started
Prerequisites
We use Tensorflow 1.15 for this implementation. Please install CUDA if you want GPU support.
pip3 install --user tensorflow-gpu==1.15.0
To install other dependencies:
pip3 install --user opencv-python
pip3 install --user open3d-python==0.7.0.0
pip3 install --user scikit-learn
pip3 install --user tqdm
pip3 install --user shapely
KITTI Dataset
We use the KITTI 3D Object Detection dataset. Please download the dataset from the KITTI website and also download the 3DOP train/val split here. We provide extra split files for seperated classes in splits/. We recommand the following file structure:
DATASET_ROOT_DIR
├── image # Left color images
│ ├── training
| | └── image_2
│ └── testing
| └── image_2
├── velodyne # Velodyne point cloud files
│ ├── training
| | └── velodyne
│ └── testing
| └── velodyne
├── calib # Calibration files
│ ├── training
| | └──calib
│ └── testing
| └── calib
├── labels # Training labels
│ └── training
| └── label_2
└── 3DOP_splits # split files.
├── train.txt
├── train_car.txt
└── ...
Download Point-GNN
Clone the repository recursively:
git clone https://github.com/WeijingShi/Point-GNN.git --recursive
Inference
Run a checkpoint
Test on the validation split:
python3 run.py checkpoints/car_auto_T3_train/ --dataset_root_dir DATASET_ROOT_DIR --output_dir DIR_TO_SAVE_RESULTS
Test on the test dataset:
python3 run.py checkpoints/car_auto_T3_trainval/ --test --dataset_root_dir DATASET_ROOT_DIR --output_dir DIR_TO_SAVE_RESULTS
usage: run.py [-h] [-l LEVEL] [--test] [--no-box-merge] [--no-box-score]
[--dataset_root_dir DATASET_ROOT_DIR]
[--dataset_split_file DATASET_SPLIT_FILE]
[--output_dir OUTPUT_DIR]
checkpoint_path
Point-GNN inference on KITTI
positional arguments:
checkpoint_path Path to checkpoint
optional arguments:
-h, --help show this help message and exit
-l LEVEL, --level LEVEL
Visualization level, 0 to disable,1 to nonblocking
visualization, 2 to block.Default=0
--test Enable test model
--no-box-merge Disable box merge.
--no-box-score Disable box score.
--dataset_root_dir DATASET_ROOT_DIR
Path to KITTI dataset. Default="../dataset/kitti/"
--dataset_split_file DATASET_SPLIT_FILE
Path to KITTI dataset split
file.Default="DATASET_ROOT_DIR/3DOP_splits/val.txt"
--output_dir OUTPUT_DIR
Path to save the detection
resultsDefault="CHECKPOINT_PATH/eval/"
Performance
Install kitti_native_evaluation offline evaluation:
cd kitti_native_evaluation
cmake ./
make
Evaluate output results on the validation split:
evaluate_object_offline DATASET_ROOT_DIR/labels/training/label_2/ DIR_TO_SAVE_RESULTS
Training
We put training parameters in a train_config file. To start training, we need both the train_config and config.
usage: train.py [-h] [--dataset_root_dir DATASET_ROOT_DIR]
[--dataset_split_file DATASET_SPLIT_FILE]
train_config_path config_path
Training of PointGNN
positional arguments:
train_config_path Path to train_config
config_path Path to config
optional arguments:
-h, --help show this help message and exit
--dataset_root_dir DATASET_ROOT_DIR
Path to KITTI dataset. Default="../dataset/kitti/"
--dataset_split_file DATASET_SPLIT_FILE
Path to KITTI dataset split file.Default="DATASET_ROOT
_DIR/3DOP_splits/train_config["train_dataset"]"
For example:
python3 train.py configs/car_auto_T3_train_train_config configs/car_auto_T3_train_config
We strongly recommand readers to view the train_config before starting the training. Some common parameters which you might want to change first:
train_dir The directory where checkpoints and logs are stored.
train_dataset The dataset split file for training.
NUM_GPU The number of GPUs to use. We used two GPUs for the reference model.
If you want to use a single GPU, you might also need to reduce the batch size by half to save GPU memory.
Similarly, you might want to increase the batch size if you want to utilize more GPUs.
Check the train.py for details.
We also provide an evaluation script to evaluate the checkpoints periodically. For example:
python3 eval.py configs/car_auto_T3_train_eval_config
You can use tensorboard to view the training and evaluation status.
tensorboard --logdir=./train_dir
License
This project is licensed under the MIT License - see the LICENSE file for details