Our moving object segmentation on the unseen SemanticKITTI test sequences 18 and 21. Red points are predicted as moving.
Please find the corresponding video here.
Given a sequence of point clouds, our method segments moving (red) from non-moving (black) points.
We first create a sparse 4D point cloud of all points in a given receding window. We use sparse 4D convolutions from the MinkowskiEngine to extract spatio-temporal features and predict per-points moving object scores.
The current state of the repository is improved by internally aligning the scans using KISS-ICP. Also, the build system and pipeline are inspired from MapMOS, so you can run it on most point cloud data formats. If you want to reproduce the original results from the paper, this version is tagged under 0.1
. You can checkout by
git checkout v0.1
First, make sure the MinkowskiEngine is installed on your system, see here for more details.
Next, clone our repository
git clone git@github.com:PRBonn/4DMOS && cd 4DMOS
and install with
make install
or
make install-all
if you want to install the project with all optional dependencies (needed for the visualizer). In case you want to edit the Python code, install in editable mode:
make editable
Just type
mos4d_pipeline --help
to see how to run 4DMOS.
Check the Download section for a pre-trained model. Like KISS-ICP, our pipeline runs on a variety of point cloud data formats like bin
, pcd
, ply
, xyz
, rosbags
, and more. To visualize these, just type
mos4d_pipeline --visualize /path/to/weights.ckpt /path/to/data
Want to evaluate with ground truth labels?
Because these labels come in all shapes, you need to specify a dataloader. This is currently available for SemanticKITTI, NuScenes, HeLiMOS, and our labeled KITTI Tracking sequence 19 and Apollo sequences (see Downloads).
To train our approach, you need to first cache your data. To see how to do that, just cd
into the 4DMOS
repository and type
python3 scripts/precache.py --help
After this, you can run the training script. Again, --help
shows you how:
python3 scripts/train.py --help
Want to verify the cached data?
You can inspect the cached training samples by using the script python3 scripts/cache_to_ply.py --help
.
Want to change the logging directory?
The training log and checkpoints will be saved by default to the current working directory. To change that, export the export LOGS=/your/path/to/logs
environment variable before running the training script.
To train on the HeLiMOS data with different sensor configurations, use the following commands:
python3 scripts/precache.py /path/to/HeLiMOS helimos /path/to/cache --config config/helimos/*_training.yaml
python3 scripts/train.py /path/to/HeLiMOS helimos /path/to/cache --config config/helimos/*_training.yaml
by replacing the paths and the config file names. To evaluate for example on the Velodyne test data, run
mos4d_pipeline /path/to/weights.ckpt /path/to/HeLiMOS --dataloader helimos -s Velodyne/test.txt
We use the SemanticKITTI API to evaluate the intersection-over-union (IOU) of the moving class as well as to visualize the predictions. Clone the repository in your workspace, install the dependencies and then run the following command to visualize your predictions for e.g. sequence 8:
cd semantic-kitti-api
./visualize_mos.py --sequence 8 --dataset /path/to/dataset --predictions /path/to/4DMOS/predictions/ID/POSES/labels/STRATEGY/
To submit the results to the LiDAR-MOS benchmark, please follow the instructions here.
- Model [A]: 5 scans @ 0.1s
- Model [B]: 5 scans @ 0.2s
- Model [C]: 5 scans @ 0.3s
- Model [D]: 5 scans, no poses
- Model [E]: 5 scans input, 1 scan output
- Model [F]: 2 scans
- Model [G]: 10 scans
If you use our code in your academic work, please cite the corresponding paper:
@article{mersch2022ral,
author = {B. Mersch and X. Chen and I. Vizzo and L. Nunes and J. Behley and C. Stachniss},
title = {{Receding Moving Object Segmentation in 3D LiDAR Data Using Sparse 4D Convolutions}},
journal={IEEE Robotics and Automation Letters (RA-L)},
year = 2022,
volume = {7},
number = {3},
pages = {7503--7510},
codeurl = {https://github.com/PRBonn/4DMOS},
}
This implementation is heavily inspired by KISS-ICP.
This project is free software made available under the MIT License. For details see the LICENSE file.