ROS2 support is here.
This package provides a set of Cartesian motion
, force
and compliance controllers
for the ROS-control
framework.
The controllers are meant for joint position
and joint velocity
interfaces on the manipulators.
As a unique selling point, they use fast forward dynamics simulations of
virtually conditioned twins of the real setup as a solver for the inverse kinematics problem.
Integrating from joint accelerations to joint velocities and joint positions
gives them a delay-free, noise suppressing, and an inherently more stable contact behavior than conventional
Admittance controllers.
The controllers from this package are designed to trade smooth and stable behavior for accuracy where
appropriate, and behave physically plausible for targets outside the robots reach.
The package is for users who require interfaces to direct task space control
without the need for collision checking.
See this talk at ROSCon'19 and the
slides
to get an overview.
Users may refer to MoveIt
for end-effector motion planning, but
integrating a full planning stack is often unnecessary for simple applications.
Additionally, there are a lot of use cases where direct control in task space is mandatory:
dynamic following of target poses, such as visual servoing, teleoperation, Cartesian teaching, or
any form of closed loop control with external sensors for physical interactions with environments, such as Machine Learning applications.
This package provides such a controller suite for the ROS-control framework.
Switch into the src
folder of your current ROS workspace and
git clone git@github.com:fzi-forschungszentrum-informatik/cartesian_controllers.git
rosdep install --from-paths ./ --ignore-src -y
cd ..
catkin_make -DCMAKE_BUILD_TYPE=Release
Source your workspace again and you are ready to go.
In a sourced terminal, call roslaunch cartesian_controller_examples examples.launch
. This will start a simulated world in which you can inspect
and try things. Here are some quick tutorials with further details:
- Solver details
- Cartesian motion controller
- Cartesian force controller
- Cartesian compliance controller
- Cartesian controller handles
- Teleoperation
If you use the cartesian_controllers in your research projects, please consider citing our initial idea of the forward dynamics-based control approach (Paper):
@InProceedings{FDCC,
Title = {Forward Dynamics Compliance Control (FDCC): A new approach to cartesian compliance for robotic manipulators},
Author = {S. Scherzinger and A. Roennau and R. Dillmann},
Booktitle = {IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)},
Year = {2017},
Pages = {4568-4575},
Doi = {10.1109/IROS.2017.8206325}
}
If you are interested in more details, have a look at
- Inverse Kinematics with Forward Dynamics Solvers for Sampled Motion Tracking (Paper)
- Virtual Forward Dynamics Models for Cartesian Robot Control (Paper)
- Contact Skill Imitation Learning for Robot-Independent Assembly Programming (Paper)
- Human-Inspired Compliant Controllers for Robotic Assembly (PhD Thesis, especially Chapter 4)