Repository Summary
Checkout URI | https://github.com/fictionlab/ros_aruco_opencv.git |
VCS Type | git |
VCS Version | humble |
Last Updated | 2024-06-04 |
Dev Status | MAINTAINED |
CI status | No Continuous Integration |
Released | RELEASED |
Tags | No category tags. |
Contributing |
Help Wanted (0)
Good First Issues (0) Pull Requests to Review (0) |
Packages
Name | Version |
---|---|
aruco_opencv | 2.3.1 |
aruco_opencv_msgs | 2.3.1 |
README
CONTRIBUTING
Repository Summary
Checkout URI | https://github.com/fictionlab/ros_aruco_opencv.git |
VCS Type | git |
VCS Version | iron |
Last Updated | 2024-06-04 |
Dev Status | MAINTAINED |
CI status | No Continuous Integration |
Released | RELEASED |
Tags | No category tags. |
Contributing |
Help Wanted (0)
Good First Issues (0) Pull Requests to Review (0) |
Packages
Name | Version |
---|---|
aruco_opencv | 5.2.1 |
aruco_opencv_msgs | 5.2.1 |
README
CONTRIBUTING
Repository Summary
Checkout URI | https://github.com/fictionlab/ros_aruco_opencv.git |
VCS Type | git |
VCS Version | jazzy |
Last Updated | 2024-06-04 |
Dev Status | MAINTAINED |
CI status | No Continuous Integration |
Released | RELEASED |
Tags | No category tags. |
Contributing |
Help Wanted (0)
Good First Issues (0) Pull Requests to Review (0) |
Packages
Name | Version |
---|---|
aruco_opencv | 6.0.1 |
aruco_opencv_msgs | 6.0.1 |
README
ROS wrapper for ArUco Opencv module
Quick start
- Prepare the camera topics.
The ROS driver for the camera you are using should publish 2 topics containing: Camera images (most commonlyimage_raw
, image_color
, image_mono
or image_rect
topic) and Camera calibration data (camera_info
topic). Both topics should be published in the same namespace. Let’s assume the driver publishes on these topics:
/camera1/image_raw
/camera1/camera_info
:warning: As of now the wrapper does not support multiple camera sources published on the same topics.
The camera should be calibrated (the better the calibration the better the marker pose estimation). If the camera is uncalibrated (the matrices D, K, R, P in camera_info
messages are set to 0) or the calibration is invalid, you should recalibrate the camera.
Also, make sure that the frame_id
published with the Camera image headers is not empty.
- Prepare the marker.
You can use scripts in aruco_opencv
package to generate PDF files with ArUco markers.
Let’s create a 0.2 x 0.2 m marker (including white margin) with ID 0:
ros2 run aruco_opencv create_marker 0
The output will look like this:
ArUco dictionary: 4X4_50
Inner marker bits: 4
Marker border bits: 1
Pixels per bit: 1
Margin pixels: 1
Marker side size: 0.1500 m - 6 pixels
Output image side size: 0.200 m - 8 pixels
Output DPI: 1.016
Generating marker with ID 0...
Converting images to pdf and writing to output file markers.pdf...
Please note the Marker side size
value. It will be passed to the marker tracker as a parameter.
Make sure to print the marker in the original scale.
- Run the marker tracker.
Start the aruco_tracker
node with cam_base_topic
parameter set to the Camera image topic name and marker_size
to the value noted in the previous step:
ros2 run aruco_opencv aruco_tracker --ros-args -p cam_base_topic:=camera1/image_raw -p marker_size:=0.15
If the images are rectified (undistorted), you should also set image_is_rectified
parameter to true
:
ros2 run aruco_opencv aruco_tracker --ros-args -p cam_base_topic:=camera1/image_rect -p image_is_rectified:=true -p marker_size:=0.075
aruco_tracker
is a Managed (Lifecycle) Node. It will start in unconfigured
state, so you will need to configure and activate it manually:
ros2 lifecycle set /aruco_opencv configure
ros2 lifecycle set /aruco_opencv activate
Alternatively you can use aruco_tracker_autostart
node which will automatically configure and activate itself:
ros2 run aruco_opencv aruco_tracker_autostart --ros-args -p cam_base_topic:=camera1/image_raw -p marker_size:=0.15
- Visualize the data.
For each received image, aruco_tracker
will publish a message on aruco_detections
topic:
ros2 topic echo /aruco_detections
Put the marker in front of the camera. If the marker is detected, the markers
array should contain the marker poses.
The marker poses are also published on TF. You can visualize the data in RViz by setting fixed frame to the frame_id
of the camera and adding the TF display.
On the /aruco_tracker/debug
topic you can see the Camera images with the frame axes of detected markers drawn on top of it.
CONTRIBUTING
Repository Summary
Checkout URI | https://github.com/fictionlab/ros_aruco_opencv.git |
VCS Type | git |
VCS Version | rolling |
Last Updated | 2024-06-04 |
Dev Status | MAINTAINED |
CI status | No Continuous Integration |
Released | RELEASED |
Tags | No category tags. |
Contributing |
Help Wanted (0)
Good First Issues (0) Pull Requests to Review (0) |
Packages
Name | Version |
---|---|
aruco_opencv | 6.0.1 |
aruco_opencv_msgs | 6.0.1 |
README
ROS wrapper for ArUco Opencv module
Quick start
- Prepare the camera topics.
The ROS driver for the camera you are using should publish 2 topics containing: Camera images (most commonlyimage_raw
, image_color
, image_mono
or image_rect
topic) and Camera calibration data (camera_info
topic). Both topics should be published in the same namespace. Let’s assume the driver publishes on these topics:
/camera1/image_raw
/camera1/camera_info
:warning: As of now the wrapper does not support multiple camera sources published on the same topics.
The camera should be calibrated (the better the calibration the better the marker pose estimation). If the camera is uncalibrated (the matrices D, K, R, P in camera_info
messages are set to 0) or the calibration is invalid, you should recalibrate the camera.
Also, make sure that the frame_id
published with the Camera image headers is not empty.
- Prepare the marker.
You can use scripts in aruco_opencv
package to generate PDF files with ArUco markers.
Let’s create a 0.2 x 0.2 m marker (including white margin) with ID 0:
ros2 run aruco_opencv create_marker 0
The output will look like this:
ArUco dictionary: 4X4_50
Inner marker bits: 4
Marker border bits: 1
Pixels per bit: 1
Margin pixels: 1
Marker side size: 0.1500 m - 6 pixels
Output image side size: 0.200 m - 8 pixels
Output DPI: 1.016
Generating marker with ID 0...
Converting images to pdf and writing to output file markers.pdf...
Please note the Marker side size
value. It will be passed to the marker tracker as a parameter.
Make sure to print the marker in the original scale.
- Run the marker tracker.
Start the aruco_tracker
node with cam_base_topic
parameter set to the Camera image topic name and marker_size
to the value noted in the previous step:
ros2 run aruco_opencv aruco_tracker --ros-args -p cam_base_topic:=camera1/image_raw -p marker_size:=0.15
If the images are rectified (undistorted), you should also set image_is_rectified
parameter to true
:
ros2 run aruco_opencv aruco_tracker --ros-args -p cam_base_topic:=camera1/image_rect -p image_is_rectified:=true -p marker_size:=0.075
aruco_tracker
is a Managed (Lifecycle) Node. It will start in unconfigured
state, so you will need to configure and activate it manually:
ros2 lifecycle set /aruco_opencv configure
ros2 lifecycle set /aruco_opencv activate
Alternatively you can use aruco_tracker_autostart
node which will automatically configure and activate itself:
ros2 run aruco_opencv aruco_tracker_autostart --ros-args -p cam_base_topic:=camera1/image_raw -p marker_size:=0.15
- Visualize the data.
For each received image, aruco_tracker
will publish a message on aruco_detections
topic:
ros2 topic echo /aruco_detections
Put the marker in front of the camera. If the marker is detected, the markers
array should contain the marker poses.
The marker poses are also published on TF. You can visualize the data in RViz by setting fixed frame to the frame_id
of the camera and adding the TF display.
On the /aruco_tracker/debug
topic you can see the Camera images with the frame axes of detected markers drawn on top of it.