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ROS wrapper for DM-VIO: Delayed Marginalization Visual-Inertial Odometry

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ROS-Wrapper for DM-VIO: Delayed Marginalization Visual-Inertial Odometry

For more information see https://vision.in.tum.de/dm-vio and https://github.com/lukasvst/dm-vio.

This is a ROS-Wrapper for DM-VIO, inspired by the ROS-Wrapper for DSO.

It interfaces with ROS topics to input images and IMU data and to output poses. Alternatively, it can read images and IMU data directly from a rosbag dataset.

Related Papers

Installation

First install DM-VIO as described here and make sure it works. This version of the ROS wrapper was tested with commit d18fa15ba086043561361941b8e5298074b34b47 of DM-VIO.

You need to set the environment variable DMVIO_BUILD to point to the folder where you built DM-VIO (which is expected to be a direct subfolder of DM-VIO). The easiest way is to put the following into your .bashrc

export DMVIO_BUILD=/PATH/TO/dm-vio/cmake-build-relwithdebinfo

Then you can clone this project into your workspace and build normally with catkin_make.

Running

You can run with

rosrun dmvio_ros node calib=/PATH/TO/camera.txt \
                      imuCalib=/PATH_TO/camchain.yaml \
                      settingsFile=/PATH_TO/dm-vio-public/configs/t265_noise_tumvi.yaml \
                      mode=1 nogui=0 preset=1 quiet=1 
                      # vignette=PATH_TO/vignette.png # highly recommended, especially for fisheye cameras (use mode=3 if vignette is set).

Most commandline arguments are the same as for DM-VIO, you will at least need to pass camera calibration, IMU camchain, preset and mode.

The node will listen for images at cam0/image_raw and for IMU messages at /imu0.

Settings file: I recommend starting with t265_noise_tumvi, and in general with TUM-VI noise values. For more details and tips see here.

Notes on exposures and photometric calibration: The standard ROS image messages do not include exposure times. If you have a custom message with exposures you can modify the method vidCb and pass the exposure to undistorter->undistort.

If you do not have exposure times you cannot use mode=0! Note that mode=1 completely disables photometric calibration, including the vignette, even if it is passed. Hence, I have added mode=3, which uses photometric calibration, but does not assume that there are exposures.

Example 1: Using EuRoC Bags

To test your installation you can download this EuRoC bag: http://robotics.ethz.ch/~asl-datasets/ijrr_euroc_mav_dataset/vicon_room2/V2_01_easy/V2_01_easy.bag

You need to create the camera.txt file using

echo -e "458.654 457.296 367.215 248.375 -0.28340811 0.07395907 0.00019359 1.76187114e-05\n752 480\ncrop\n640 480\n" > camera.txt

Then you can run the following commands in separate terminals

rosrun dmvio_ros node calib=/PATH/TO/camera.txt settingsFile=/PATH/TO/dm-vio/configs/euroc.yaml mode=1 nogui=0 preset=1 useimu=1 quiet=1 init_requestFullResetNormalizedErrorThreshold=0.8 init_pgba_skipFirstKFs=1

rosbag play V2_01_easy.bag

New: Now you can also run in non-realtime mode on rosbags

For EuRoC, simply run the following command in a terminal. (Make sure that roscore is running in a separate terminal.)

rosrun dmvio_ros node calib=/PATH/TO/camera.txt settingsFile=/PATH/TO/dm-vio/configs/euroc.yaml mode=1 nogui=0 preset=1 useimu=1 quiet=1 init_requestFullResetNormalizedErrorThreshold=0.8 init_pgba_skipFirstKFs=1 rosbag=/PATH/TO/V2_01_easy.bag loadRosbagThread=1

This command will run as fast as possible and exit once execution is complete, which makes it useful to run on rosbag datasets. If a dataset is available as a rosbag, this is more convenient than extracting the rosbag and running the non-ros version of DM-VIO. However, keep in mind that ROS does not support exposure times out of the box, which can result in slightly worse accuracy compared to a dataset with full photometric calibration (including exposure times).

Example 2: Running on Realense T265

You can run on the Realsense T265 with their provided ROS driver. Install it with

sudo apt-get install ros-$ROS_DISTRO-realsense2-camera

Then you can run the following commands in separate terminals

rosrun dmvio_ros node nogui=0 useimu=1 quiet=1 mode=3 `#we use mode 3 because we have vignette but no expusures` \
                      calib=/PATH_TO/RealsenseCalibration/camera.txt \
                      imuCalib=/PATH_TO/RealsenseCalibration/factory_camchain.yaml \
                      gamma=PATH_TO/dm-vio/configs/pcalib_linear_8bit.txt \
                      vignette=PATH_TO/dm-vio/configs/realsense/vignette_t265.png \
                      settingsFile=/PATH_TO/dm-vio/configs/t265_noise_tumvi.yaml \
                      resultsPrefix=/PATH_TO_RESULTS/ \
                      cam0/image_raw:=/camera/fisheye1/image_raw imu0:=/camera/imu # Remap topics

roslaunch realsense2_camera rs_t265.launch unite_imu_method:=linear_interpolation enable_fisheye1:=true enable_fisheye2:=true enable_pose:=false

The camera.txt and factory_camchain.txt can be obtained by calibrating yourself or by first running the normal Realsense demo which will save the factory calibration.

Note that the ROS driver does not read out exposures, hence we need to use mode=3 instead of mode=1 and the accuracy can be a bit worse than with the normal Realsense demo.

Published topics

When using this ROS wrapper you might want to change src/ROSOutputWrapper.cpp to publish information in a format suited to your application.

We publish the following topics by default:

dmvio/frame_tracked: DMVIOPoseMsg

Published for every tracked frame (except the inital two frames). It includes

  • geometry_msgs/Pose pose: Transformation from camera to world in DSO frame (meaning it can have an arbitrary scale).

and all fields in transformDSOToIMU, which enables you to convert the pose (and all published poses prior to this) to the metric frame:

  • float64 scale
  • geometry_msgs/Quaternion rotationMetricToDSO: Gravity direction encoded as the rotation to convert from metric world to DSO world
  • geometry_msgs/Pose imuToCam: Transformation between camera and IMU

dmvio/unscaled_pose: PoseStamped

This is just a copy of /dmvio/frame_tracked/pose. It can be useful for visualizing in Rviz as PoseStamped is a standard message. Note that the used coordinate system is camera-based (see below), which is why it can look strange in Rviz.

dmvio/metric_pose: PoseStamped

These poses are the transformation from IMU to world (in metric scale). We provide this for convenience but for many applications you should not directly subscribe to this topic, but rather convert the poses yourself using the newest scale.

The reason is that these metric poses are all converted with the scale estimated at the time they were published. But when you perform computations on the entire trajectory you want to convert all poses with the newest scale instead.

dmvio/system_status: Int32

This is a number, indicating the status the system is in (0 means visual initializer, 1 means visual-only mode and 2 means visual-inertial mode). For details see the enum dmvio::SystemStatus. Whenever a full reset happens, 0 is sent to this topic again.

Coordinate system

As mentioned the poses are either in metric or in DSO frame, for converting between the two see TransformDSOToIMU::transformPose or equation (5) in the DM-VIO paper.

We use the typical camera-based coordinate frame, where x points to the right of the image, y points down and z points forward (into the camera).

What is not published / implemented and what you might want to implement yourself:

  • The keyframes after bundle adjustment: These will be more accurate than the initially tracked frame poses. You can access them as well as the pointcloud by overriding publishKeyframes in ROSOutputWrapper.cpp. You could take inspiration from how it was implemented in LSD-SLAM.
  • TF frames
  • Dynamic reconfigure

License

This ROS wrapper is licensed under the GNU General Public License 3 (GPLv3). The main.cpp file reuses code from the main file of DSO.

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