Control interface built on top of franka_ros that allows to control the franka robot arm in several joint and Cartesian space impedance control schemes for interactive, safe and reactive (mostly DS-based) motion planning and learning. This low-level control interface is used and developed by/for Prof. Nadia Figueroa and her collaborators and students. Initially developed at MIT in the Interactive Robotics Group continued development at the University of Pennsylvania.
Besides franka_ros and by consequence libfranka this package depends on several other code repositories that are robot-agnostic and useful for control and learning of motion policies from demonstrations.
To install this repo and all its dependencies do the following steps:
- In your catkin src directory clone the repository
$ git clone https://github.com/nbfigueroa/franka_interactive_controllers.git
- wstool gets all other git repository dependencies, after the following steps you should see extra catkin packages in your src directory.
$ wstool init
$ wstool merge franka_interactive_controllers/dependencies.rosinstall
$ wstool up
- Query and installs all libraries and packages
$ rosdep install --from-paths . --ignore-src --rosdistro <your-ros-distro>
- Install some additional python dependencies
$ sudo apt install python3-psutil python3-tkinter
- Finally complie
$ cd ~/catkin_ws
$ catkin_make
$ source devel/setup.bash
$ catkin_make
$ rospack profileYou might need to source the ./bashrc file and compile again if the first compliation could not find some of the in-house dependencies. If roscd doesn't find the compiled packages run rospack profile.
We include a list of instructions for using the franka panda arm with this controller package:
- Startup the robot
- External tool compensation (necessary if your experiment requires mounting a tool/accesory on the franka hand)
- Basic robot operating functionalities (open/close gripper and move robot to a desired joint position bypassing franka_ros -- useful to startup an experiment).
- Kinesthetic Teaching + Data Collection and Pre-Processing
- Learning DS motion policies
- Executing DS motion policies
- Executing custom motion policies (MPC, feed-forward NN, DMP, etc)
Following we detail instructions on how to bringup the controllers and their functionalities:
To bring up the standalone robot with franka_ros without any specific controller (useful for testing -- can be included in your custom launch file):
roslaunch franka_interactive_controllers franka_interactive_bringup.launch This will load all franka_ros (franka_control, franka_gripper, etc.) functionalities + gripper GUI controller + configured rviz settings.
To load the joint gravity compensation controller launch the following:
roslaunch franka_interactive_controllers joint_gravity_compensation_controller.launch- This will load a joint gravity compensation torque controller. It compensates (from code) the weight of any additional tool (i.e., a tool grasped by the hand or cameras mounted on the gripper). As well as the capability to lock certain joints for ease of demonstration.
- The external forces imposed on the end-effector with the additional weight should be defined in
./config/external_tool_compensation.yaml. Instructions on how to finding values for your custom tool here. You can toggle to activate/deactivate this compensation online using dynamic reconfigure. Default is set totrue. - The desired joints to lock and the locked positions can be modified online by dynamic reconfigure. Default is set to
falsefor all locks. - To launch
franka_interactive_bringup.launchwithin this same launch fileset load_franka_control:=true. Default is set tofalse.
NOTE: If you run this script and the robot moves by itself, that means that your external_tool_compensation forces are incorrect. See external_tool_compensation instructions to correct it.
You can launch the joint gravity compensation controller together with data recording nodes from my easy-kinesthetic-teaching repository latest-franka branch.
roslaunch franka_interactive_controllers franka_kinesthetic_teaching.launchIf you installed and compiled everything correctly you should see the following windows on your screen:
This will run scripts and nodes that will allow you to:
- Select topics to record and define path to save rosbags.
- Run all functionalities from joint gravity compensation controller.
- Bringup rosservice to record/stop a recording.
- Visualize end-effector trajectories being recorded in real-time and gripper state (open/closed).
- Replay recorded end-effector trajectoriers and gripper state in RViz, franka controllers and launch files must be turned off for this functionality.
See Kinesthetic Teaching/Recording instructions for definitions and usage.
To load a cartesian impedance controller with pose command (a PD control law with position error tracking; i.e., stiffness control and velocity damping) launch the following:
roslaunch franka_interactive_controllers cartesian_pose_impedance_controller.launchThis launch file will load a cartesian impedance controller that:
- Takes as input a desired end-effector pose (position and orientation) as a
geometry_msg::PoseStampedwith topic name/cartesian_impedance_controller/desired_pose. - Will compensate for external forces imposed by additional tools/accesories mounted on the gripper (as described in joint gravity compensation controller above).
- Control for a desired nullspace configuration, defined in config/impedance_control_additional_params.yaml, stiffness for nullspace control can be modified online by dynamic reconfigure.
To load a cartesian impedance controller with twist command (a PD control law with position and velocity error tracking) launch the following:
roslaunch franka_interactive_controllers cartesian_twist_impedance_controller.launchThis launch file will load a cartesian impedance controller that:
- Takes as input a desired end-effector twist (linear and angular velocity) as a
geometry_msg::Twistwith topic name/cartesian_impedance_controller/desired_twist. - Will compensate for external forces imposed by additional tools/accesories mounted on the gripper (as described in joint gravity compensation controller above).
- Control for a desired nullspace configuration, defined in config/impedance_control_additional_params.yaml, stiffness for nullspace control can be modified online by dynamic reconfigure.
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Maintainer: Nadia Figueroa (nadiafig @ seas dot upenn edu)
Code Contributions by: Bilkit Githinji, Shen Li.
Please note that the code for some of the controllers in this repository is derived from franka_ros, specifically the franka_example_controllers package which is licenced under Apache 2.0. The remaining code in the repository is licensed under an MIT license (see LICENSE for details).