Kinova® Kortex™ is the common software platform behind all of the products in the Gen3 family (Gen3 and Gen3 lite). It unifies the inner workings of the various robots and their related external tools, like the API.
https://www.kinovarobotics.com/product/gen3-robots
ROS2 Kortex is the official ROS2 package to interact with Kortex and its related products. It is built upon the Kortex API, documentation for which can be found in the GitHub Kortex repository.
ROS 2 Distro | Humble | Iron | Rolling |
---|---|---|---|
Branch | main | main | main |
Build Status | |||
Release Status | coming soon | coming soon | coming soon |
Note: There are several CI jobs checking against future upstream changes see detailed build status for a full list of CI jobs and for more information.
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Install ROS 2.
If you're a developer, we recommend using Rolling to get the latest features and fixes.
Rolling Release: Install ROS2 Rolling
Latest Release: Install ROS2 Iron
Stable LTS Release: Install ROS2 HumbleAfter installing a version of ROS, source the setup.bash, which will set the
$ROS_DISTRO
environment variable. -
Install this package from binary
sudo apt install ros-$ROS_DISTRO-kortex-bringup
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Optional: install MoveIt Configuration and Cyclone DDS
If you have a 7dof arm:
sudo apt install ros-$ROS_DISTRO-kinova-gen3-7dof-robotiq-2f-85-moveit-config
If you have a 6dof arm:
sudo apt install ros-$ROS_DISTRO-kinova-gen3-6dof-robotiq-2f-85-moveit-config
If you plan to use MoveIt, it is recommended to install and use Cyclone DDS.
sudo apt install ros-$ROS_DISTRO-rmw-cyclonedds-cpp export RMW_IMPLEMENTATION=rmw_cyclonedds_cpp
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Go to Usage section
Note: It is recommended to use a released binary version of this package and apt install it. If you want the latest version of this repository for testing latest fixes check out testing with pre-released binaries: https://docs.ros.org/en/rolling/Installation/Testing.html
If the bug fix you need isn't in a released version or If you want to build this repository from source or contribute back to the repository read on.
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Make sure that
colcon
, its extensions, andvcs
are installed:sudo apt install python3-colcon-common-extensions python3-vcstool
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Create a new ROS2 workspace:
export COLCON_WS=~/workspace/ros2_kortex_ws mkdir -p $COLCON_WS/src
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Pull relevant packages, install dependencies, compile, and source the workspace by using:
cd $COLCON_WS git clone https://github.com/PickNikRobotics/ros2_kortex.git src/ros2_kortex rosdep install --ignore-src --from-paths src -y -r colcon build --cmake-args -DCMAKE_BUILD_TYPE=Release source install/setup.bash
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To simulate the robot with ignition or gazebo make sure to pull and build additional packages:
vcs import src --skip-existing --input src/ros2_kortex/simulation.repos rosdep install --ignore-src --from-paths src -y -r colcon build --cmake-args -DCMAKE_BUILD_TYPE=Release source install/setup.bash
Please note, at this time there are two known issues you with simulation
- Gazebo + Mimic Joints for the Robotiq Gripper
- Protobuf version mismatch
A pull request has been made to gz_ros2_control which is how this repository was tested in simulation. The pull request won't be merged as the fix should be done upstream in gz-sim. Once a fix is available ros2_robotiq_gripper will be re-released and an update should fix any workarounds.
In the meantime if you need simulation checkout the upstream pull request link:
- Upstream Issue: gazebosim/gz-sim#1684
- Upstream Pull Request: ros-controls/gz_ros2_control#86
- Tracking Issue: PickNikRobotics/ros2_robotiq_gripper#7
Due to mismatched protobuf version that ships system and used by Gazebo simulator compiling twice may be required. You will only run into this if you have certain other gazebo related code in your workspace while compiling this repository. If errors are encounter you must clean your workspace and run colcon build in two steps:
- build everything except kortex related packages
- build the packages that where skipped
sudo apt install python3-colcon-clean # if you don't have colcon-clean installed already
colcon clean workspace -y
colcon build --packages-skip-regex '.*kortex.*' '.*gen3.*'
colcon build --packages-select-regex '.*kortex.*' '.*gen3.*'
To launch and view the robots URDF run:
ros2 launch kortex_description view_robot.launch.py
To simulate the 7 DoF Kinova Gen3 robot arm with mock hardware:
ros2 launch kortex_bringup gen3.launch.py \
robot_ip:=yyy.yyy.yyy.yyy \
use_fake_hardware:=true
To generate motion plans and execute them with a simulated 7 DoF Kinova Gen3 arm with mock hardware:
ros2 launch kinova_gen3_7dof_robotiq_2f_85_moveit_config robot.launch.py \
robot_ip:=yyy.yyy.yyy.yyy \
use_fake_hardware:=true
Alternatively, if you wish to use the Kinova Gen3's 6 DoF variant:
ros2 launch kortex_bringup gen3.launch.py \
robot_ip:=yyy.yyy.yyy.yyy \
use_fake_hardware:=true \
dof:=6
and to bring up the Kinova Gen3 6 DoF with MoveIt:
ros2 launch kinova_gen3_6dof_robotiq_2f_85_moveit_config robot.launch.py \
robot_ip:=yyy.yyy.yyy.yyy \
use_fake_hardware:=true
Alternatively, if you wish to use the Kinova Gen3_lite's 6 DoF variant:
ros2 launch kortex_bringup gen3.launch.py \
robot_ip:=yyy.yyy.yyy.yyy \
use_fake_hardware:=true \
robot_type:=gen3_lite \
gripper:=gen3_lite_2f \
dof:=6
To simulate the 7dof Kinova Gen3 robot with ignition run the following:
ros2 launch kortex_bringup kortex_sim_control.launch.py \
dof:=7 \
use_sim_time:=true \
launch_rviz:=false
and to use MoveIt to command the robot:
ros2 launch kinova_gen3_7dof_robotiq_2f_85_moveit_config sim.launch.py \
use_sim_time:=true
To work with a physical robot and generate/execute paths with MoveIt run the following:
ros2 launch kinova_gen3_7dof_robotiq_2f_85_moveit_config robot.launch.py \
robot_ip:=192.168.1.10
Note: If you have reassigned your physical arm's robot IP address, then you will need to assign that ip address to robot_ip
You can command the arm by publishing Joint Trajectory messages directly to the joint trajectory controller:
ros2 topic pub /joint_trajectory_controller/joint_trajectory trajectory_msgs/JointTrajectory "{
joint_names: [joint_1, joint_2, joint_3, joint_4, joint_5, joint_6, joint_7],
points: [
{ positions: [0, 0, 0, 0, 0, 0, 0], time_from_start: { sec: 10 } },
]
}" -1
You can also command the arm using Twist messages. Before doing so, you must active the twist_controller
and deactivate the joint_trajectory_controller
:
ros2 service call /controller_manager/switch_controller controller_manager_msgs/srv/SwitchController "{
activate_controllers: [twist_controller],
deactivate_controllers: [joint_trajectory_controller],
strictness: 1,
activate_asap: true,
}"
Note: the required interface for the twist_controller
does not currently exist in the gazebo or mock hardware simulation setups. So the twist_controller
is currently only functional on Kinova hardware.
Once the twist_controller
is activated, You can publish Twist messages on the /twist_controller/commands
topic to command the arm.
For example, you can jog the arm using Teleop Twist Keyboard with the following command:
WARNING: you are responsible for collision checking, including self collisions when in this mode.
ros2 run teleop_twist_keyboard teleop_twist_keyboard --ros-args --remap /cmd_vel:=/twist_controller/commands
If you wish to use the joint_trajectory_controller
again to command the arm using JointTrajectory messages, run the following:
ros2 service call /controller_manager/switch_controller controller_manager_msgs/srv/SwitchController "{
activate_controllers: [joint_trajectory_controller],
deactivate_controllers: [twist_controller],
strictness: 1,
activate_asap: true,
}"
The Robotiq 2f 85 Gripper will be available on the Action topic:
/robotiq_gripper_controller/gripper_cmd
You can test the gripper by calling the Action server with the following command and setting the desired position
of thr gripper (0.0=open
, 0.8=close
)
ros2 action send_goal /robotiq_gripper_controller/gripper_cmd control_msgs/action/GripperCommand "{command:{position: 0.0, max_effort: 100.0}}"
The following is a description of the packages included in this repository.
This package contains the URDF (Unified Robot Description Format), STL and configuration files for the Kortex-compatible robots. For more details, please consult the README from the package subdirectory.
This package implements a ROS node that allows communication between a node and a Kinova Gen3 or Gen3 lite robot. For more details, please consult the README from the package subdirectory.
This metapackage contains the auto-generated MoveIt! files to use the Kinova Gen3 and Gen3 lite arms with the MoveIt! motion planning framework. For more details, please consult the README from the package subdirectory.