2b-t / closed_loop

Work-around for including parallel robots into the Robot Operating System ROS (URDF) and Gazebo (SDF)
MIT License
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robotics ros sdf urdf urdf-model urdf-models xacro

Closed loop parallel robots in ROS and Gazebo with SDF-code injection - Four-bar linkage example

Author: Tobit Flatscher (April 2020)

0. Overview

This is a workaround on how to include parallel robots into Robot Operating System ROS (URDF) and GazeboSim (SDF) by using Xacro without having to retype the geometry manually twice for the URDF and the SDF-files. This works by injecting SDF code into the URDF file. Only years after creating this repository I noticed that there are similar examples available online on Gazebo and also the PR2 uses a similar approach. As the only remaining advantage of this repository is that it comes with a Docker, I decided to archive this repository.

0.1 The issue

The Unified Robot Description Format (UDRF) only supports serial chains (meaning a parent may have multiple child nodes but a child only a single parent node) and therefore can't describe parallel robots due to their graph structure with closed loops (two parents for at least one link). Simulation with Gazebo on the other hand supports parallel geometries such as the Simulation Description Format (SDF). As a consequence both files are often written manually, making it error prone in case the geometry changes. A previous workaround (that is anyways more complicated) did not work for me, so I had to come up with my own solution. In this workaround closed loops are broken up into serial chains and the missing joints are supplied to only Gazebo with corresponding instructions in SDF. Furthermore it introduces XML macros with Xacro to reduce code redundancy. In the process a single UDRF that can be saved on the ROS parameter server is generated that still contains the SDF to automatically recover the full parallel geometry in Gazebo.

0.2 The files

The files simulate a simple four-bar linkage similar to the example in SDF by The Construct that collapses to the side under gravity.

.
├── doc/                          # contains additional documentation:
│   ├── doc/Adapt.md              # describes how you can adapt the same principle to your parallel robot
│   └── doc/Docker.md             # describes how the supplied Docker can be used
├── docker/                       # contains several Docker and Docker-Compose configurations
├── launch/closed_loop.launch.py  # the mainlaunch file
├── urdf/
│   ├── closed_loop.urdf.xacro    # the main URDF Xacro
│   ├── element.xacro             # contains definition of a single element
│   └── parameters.xacro          # contains geometry parameters
├── .devcontainer/                # contains configuration files for containers in Visual Studio Code
└── .vscode/                      # contains configuration files for Visual Studio Code

1.1 Launch the solution

You can either download this repository directly and place it as a package into an existing ROS workspace or used the supplied Docker as discussed in more detail in doc/Docker.md.

Rebuild your workspace (assuming you named it closed_loop_ws and placed it inside home) with

$ cd ~/closed_loop_ws
$ colcon build

Run the launch file that opens Gazebo, loads the URDF and spawns it into Gazebo

$ source install/setup.bash
$ ros2 launch closed_loop closed_loop.launch.py

This should bring up a simple four-bar linkage in Gazebo that collapses to the side.

2. Adapt it to your robot

For more information on how to adapt this principle to your robot have a look at the file doc/Adapt.md.

2.1 Known issues

Additionally to the given example of a four-bar-linkage I have successfully used this approach with 1R2T and 3R3T cable-driven parallel robots. It seems though as if there might be some limitations to this approach as discussed in issue #1. I have made a couple of test but could not find out yet in which situations it would work and in which it would fail. Similarly ros_control sometimes does not seem to work with this approach.