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https://github.com/koide3/hdl_graph_slam
3D LIDAR-based Graph SLAM
https://github.com/koide3/hdl_graph_slam
hdl-graph-slam lidar point-cloud ros rslidar slam velodyne
Last synced: 5 days ago
JSON representation
3D LIDAR-based Graph SLAM
- Host: GitHub
- URL: https://github.com/koide3/hdl_graph_slam
- Owner: koide3
- License: bsd-2-clause
- Created: 2018-01-01T07:35:43.000Z (almost 7 years ago)
- Default Branch: master
- Last Pushed: 2024-07-16T01:39:14.000Z (6 months ago)
- Last Synced: 2024-10-30T03:44:39.204Z (2 months ago)
- Topics: hdl-graph-slam, lidar, point-cloud, ros, rslidar, slam, velodyne
- Language: C++
- Homepage:
- Size: 3.86 MB
- Stars: 1,999
- Watchers: 76
- Forks: 729
- Open Issues: 123
-
Metadata Files:
- Readme: README.md
- License: LICENSE
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README
# New SLAM package is released
A new 3D SLAM package is released: https://github.com/koide3/glim.
# hdl_graph_slam
***hdl_graph_slam*** is an open source ROS package for real-time 6DOF SLAM using a 3D LIDAR. It is based on 3D Graph SLAM with NDT scan matching-based odometry estimation and loop detection. It also supports several graph constraints, such as GPS, IMU acceleration (gravity vector), IMU orientation (magnetic sensor), and floor plane (detected in a point cloud). We have tested this package with Velodyne (HDL32e, VLP16) and RoboSense (16 channels) sensors in indoor and outdoor environments.[![Build](https://github.com/koide3/hdl_graph_slam/actions/workflows/build.yml/badge.svg)](https://github.com/koide3/hdl_graph_slam/actions/workflows/build.yml) on melodic & noetic
## Third-party extensions
See also the following nice works built upon hdl_graph_slam. Feel free to request to include your work in the list :)
- Multi-Robot Mapping (ROS2) developed by [Andreas Serov](https://github.com/aserbremen) : [aserbremen/Multi-Robot-Graph-SLAM](https://github.com/aserbremen/Multi-Robot-Graph-SLAM)
- [CURB-SG: Collaborative Dynamic 3D Scene Graphs](http://curb.cs.uni-freiburg.de/) developed by Elias Greve : [robot-learning-freiburg/CURB-SG](https://github.com/robot-learning-freiburg/CURB-SG)## Nodelets
***hdl_graph_slam*** consists of four nodelets.- *prefiltering_nodelet*
- *scan_matching_odometry_nodelet*
- *floor_detection_nodelet*
- *hdl_graph_slam_nodelet*The input point cloud is first downsampled by *prefiltering_nodelet*, and then passed to the next nodelets. While *scan_matching_odometry_nodelet* estimates the sensor pose by iteratively applying a scan matching between consecutive frames (i.e., odometry estimation), *floor_detection_nodelet* detects floor planes by RANSAC. The estimated odometry and the detected floor planes are sent to *hdl_graph_slam*. To compensate the accumulated error of the scan matching, it performs loop detection and optimizes a pose graph which takes various constraints into account.
## Constraints (Edges)
You can enable/disable each constraint by changing params in the launch file, and you can also change the weight (\*_stddev) and the robust kernel (\*_robust_kernel) of each constraint.
- ***Odometry***
- ***Loop closure***
- ***GPS***
- */gps/geopoint* (geographic_msgs/GeoPointStamped)
- */gps/navsat* (sensor_msgs/NavSatFix)
- */gpsimu_driver/nmea_sentence* (nmea_msgs/Sentence)hdl_graph_slam supports several GPS message types. All the supported types contain (latitude, longitude, and altitude). hdl_graph_slam converts them into [the UTM coordinate](http://wiki.ros.org/geodesy), and adds them into the graph as 3D position constraints. If altitude is set to NaN, the GPS data is treated as a 2D constrait. GeoPoint is the most basic one, which consists of only (lat, lon, alt). Although NavSatFix provides many information, we use only (lat, lon, alt) and ignore all other data. If you're using HDL32e, you can directly connect *hdl_graph_slam* with *velodyne_driver* via */gpsimu_driver/nmea_sentence*.
- ***IMU acceleration (gravity vector)***
- */gpsimu_driver/imu_data* (sensor_msgs/Imu)This constraint rotates each pose node so that the acceleration vector associated with the node becomes vertical (as the gravity vector). This is useful to compensate for accumulated tilt rotation errors of the scan matching. Since we ignore acceleration by sensor motion, you should not give a big weight for this constraint.
- ***IMU orientation (magnetic sensor)***
- */gpsimu_driver/imu_data* (sensor_msgs/Imu)If your IMU has a reliable magnetic orientation sensor, you can add orientation data to the graph as 3D rotation constraints. Note that, magnetic orientation sensors can be affected by external magnetic disturbances. In such cases, this constraint should be disabled.
- ***Floor plane***
- */floor_detection/floor_coeffs* (hdl_graph_slam/FloorCoeffs)This constraint optimizes the graph so that the floor planes (detected by RANSAC) of the pose nodes becomes the same. This is designed to compensate the accumulated rotation error of the scan matching in large flat indoor environments.
## Parameters
All the configurable parameters are listed in *launch/hdl_graph_slam.launch* as ros params.## Services
- */hdl_graph_slam/dump* (hdl_graph_slam/DumpGraph)
- save all the internal data (point clouds, floor coeffs, odoms, and pose graph) to a directory.
- */hdl_graph_slam/save_map* (hdl_graph_slam/SaveMap)
- save the generated map as a PCD file.## Requirements
***hdl_graph_slam*** requires the following libraries:- OpenMP
- PCL
- g2o
- suitesparseThe following ROS packages are required:
- geodesy
- nmea_msgs
- pcl_ros
- [ndt_omp](https://github.com/koide3/ndt_omp)
- [fast_gicp](https://github.com/SMRT-AIST/fast_gicp)```bash
# for melodic
sudo apt-get install ros-melodic-geodesy ros-melodic-pcl-ros ros-melodic-nmea-msgs ros-melodic-libg2o
cd catkin_ws/src
git clone https://github.com/koide3/ndt_omp.git -b melodic
git clone https://github.com/SMRT-AIST/fast_gicp.git --recursive
git clone https://github.com/koide3/hdl_graph_slamcd .. && catkin_make -DCMAKE_BUILD_TYPE=Release
# for noetic
sudo apt-get install ros-noetic-geodesy ros-noetic-pcl-ros ros-noetic-nmea-msgs ros-noetic-libg2ocd catkin_ws/src
git clone https://github.com/koide3/ndt_omp.git
git clone https://github.com/SMRT-AIST/fast_gicp.git --recursive
git clone https://github.com/koide3/hdl_graph_slamcd .. && catkin_make -DCMAKE_BUILD_TYPE=Release
```**[optional]** *bag_player.py* script requires ProgressBar2.
```bash
sudo pip install ProgressBar2
```## Example1 (Indoor)
Bag file (recorded in a small room):
- [hdl_501.bag.tar.gz](http://www.aisl.cs.tut.ac.jp/databases/hdl_graph_slam/hdl_501.bag.tar.gz) (raw data, 344MB)
- [hdl_501_filtered.bag.tar.gz](http://www.aisl.cs.tut.ac.jp/databases/hdl_graph_slam/hdl_501_filtered.bag.tar.gz) (downsampled data, 57MB, **Recommended!**)
- [Mirror link](https://zenodo.org/record/6960371)```bash
rosparam set use_sim_time true
roslaunch hdl_graph_slam hdl_graph_slam_501.launch
``````bash
roscd hdl_graph_slam/rviz
rviz -d hdl_graph_slam.rviz
``````bash
rosbag play --clock hdl_501_filtered.bag
```We also provide bag_player.py which automatically adjusts the playback speed and processes data as fast as possible.
```bash
rosrun hdl_graph_slam bag_player.py hdl_501_filtered.bag
```You'll see a point cloud like:
You can save the generated map by:
```bash
rosservice call /hdl_graph_slam/save_map "resolution: 0.05
destination: '/full_path_directory/map.pcd'"
```## Example2 (Outdoor)
Bag file (recorded in an outdoor environment):
- [hdl_400.bag.tar.gz](http://www.aisl.cs.tut.ac.jp/databases/hdl_graph_slam/hdl_400.bag.tar.gz) (raw data, about 900MB)
- [Mirror link](https://zenodo.org/record/6960371)```bash
rosparam set use_sim_time true
roslaunch hdl_graph_slam hdl_graph_slam_400.launch
``````bash
roscd hdl_graph_slam/rviz
rviz -d hdl_graph_slam.rviz
``````bash
rosbag play --clock hdl_400.bag
```
## Example with GPS
Ford Campus Vision and Lidar Data Set [\[URL\]](http://robots.engin.umich.edu/SoftwareData/Ford)The following script converts the Ford Lidar Dataset to a rosbag and plays it. In this example, ***hdl_graph_slam*** utilizes the GPS data to correct the pose graph.
```bash
cd IJRR-Dataset-2
rosrun hdl_graph_slam ford2bag.py dataset-2.bag
rosrun hdl_graph_slam bag_player.py dataset-2.bag
```
## Use hdl_graph_slam in your system
1. Define the transformation between your sensors (LIDAR, IMU, GPS) and base_link of your system using static_transform_publisher (see line #11, hdl_graph_slam.launch). All the sensor data will be transformed into the common base_link frame, and then fed to the SLAM algorithm.
2. Remap the point cloud topic of ***prefiltering_nodelet***. Like:
```bash
...
```## Common Problems
### Parameter tuning guide
The mapping quality largely depends on the parameter setting. In particular, scan matching parameters have a big impact on the result. Tune the parameters accoding to the following instructions:
- ***registration_method***
**[updated] In short, use FAST_GICP for most cases and FAST_VGICP or NDT_OMP if the processing speed matters** This parameter allows to change the registration method to be used for odometry estimation and loop detection. Note that GICP in PCL1.7 (ROS kinetic) or earlier has a bug in the initial guess handling. **If you are on ROS kinectic or earlier, do not use GICP**.- ***ndt_resolution***
This parameter decides the voxel size of NDT. Typically larger values are good for outdoor environements (0.5 - 2.0 [m] for indoor, 2.0 - 10.0 [m] for outdoor). If you chose NDT or NDT_OMP, tweak this parameter so you can obtain a good odometry estimation result.- ***other parameters***
All the configurable parameters are available in the launch file. Copy a template launch file (hdl_graph_slam_501.launch for indoor, hdl_graph_slam_400.launch for outdoor) and tweak parameters in the launch file to adapt it to your application.## License
This package is released under the BSD-2-Clause License.
Note that the cholmod solver in g2o is licensed under GPL. You may need to build g2o without cholmod dependency to avoid the GPL.
## Related packages
- [interactive_slam](https://github.com/koide3/interactive_slam)
- [hdl_graph_slam](https://github.com/koide3/hdl_graph_slam)
- [hdl_localization](https://github.com/koide3/hdl_localization)
- [hdl_people_tracking](https://github.com/koide3/hdl_people_tracking)## Papers
Kenji Koide, Jun Miura, and Emanuele Menegatti, A Portable 3D LIDAR-based System for Long-term and Wide-area People Behavior Measurement, Advanced Robotic Systems, 2019 [[link]](https://www.researchgate.net/publication/331283709_A_Portable_3D_LIDAR-based_System_for_Long-term_and_Wide-area_People_Behavior_Measurement).## Contact
Kenji Koide, [email protected], https://staff.aist.go.jp/k.koideActive Intelligent Systems Laboratory, Toyohashi University of Technology, Japan [\[URL\]](http://www.aisl.cs.tut.ac.jp)
Mobile Robotics Research Team, National Institute of Advanced Industrial Science and Technology (AIST), Japan [\[URL\]](https://unit.aist.go.jp/hcmrc/mr-rt/contact.html)