ROSBuzz is a ROS node encompassing Buzz Virtual Machine (BVM) and interfacing with ROS ecosystem for mobile robots. The only node of the package is rosbuzz_node
. It can be used in simulation-in-the-loop using Gazebo and was tested over many platforms (Clearpath Husky, DJI M100, Intel Aero, 3DR Solos, Pleidis Spiris, etc.). More information about ROSBuzz peripheral nodes is available in [1].
Buzz is a novel programming language for heterogeneous robots swarms. Buzz advocates a compositional approach, by offering primitives to define swarm behaviors both in a bottom-up and in a top-down fashion. Its official documentation and code are available Buzz.
- Buzz:
Follow the required steps in Buzz.
- ROS base binary distribution (Indigo or higher):
Follow the required steps in ROS Kinetic. Note that the guidance and camera node of DJI for the M100 require to use the Indigo distribution.
- ROS additionnal dependencies:
$ sudo apt-get install ros-<distro>-mavros ros-<distro>-mavros-extras
mkdir -p ROS_WS/src
cd ROS_WS/src
git clone https://github.com/MISTLab/ROSBuzz rosbuzz
cd ..
catkin_make -DSIM=0 -DKIN=1
Flags to be passed during compilation.
Flag | Rationale |
---|---|
-DSIM | Indicates Compilation for robot or Simulation. |
-DKIN | Indicates compilation for ROS Distro Kinetic |
source /opt/ros/kinetic/setup.bash
source ~/ROS_WS/devel/setup.bash
To run the ROSBuzz package using the launch file, execute the following:
$ roslaunch rosbuzz rosbuzz.launch
Have a look at the launch file to understand what parameters are available to suit your usage. All topics and services names are listed in launch_config/topics.yaml
. Note : Before launching the ROSBuzz node, verify all the parameters in the launch file. A launch file using gdb is available too (rosbuzzd.launch).
A launch file for a groundstation is also available launch/groundstation.launch
. It uses the robot ID = 0, which is detected as a groundstation by our Buzz scripts. It also has hardcoded GPS coordinates to avoid the need of a GPS sensor on the groundstation. While a groundstation is never required to deploy a swarm with ROSBuzz, it opens a websocket on ROS, useful to monitor the swarm and it creates a rosbag of the flight.
- Buzz scripts: Several behavioral scripts are included in the "buzz_Scripts" folder, such as "graphformGPS.bzz" uses in [1] and the "testaloneWP.bzz" to control a single drone with a ".csv" list of waypoints. The script "empty.bzz" is a template script.
-
Messages from Buzz (BVM): The node publishes
mavros_msgs/Mavlink
message "outMavlink". -
Command to the flight controller: The node publishes
geometry_msgs/PoseStamped message
"setpoint_position/local". -
Other information from the swarw: The node publishes:
- "bvmstate" (
std_msgs/String
) - "neighbours_pos" (
rosbuzz_msgs/neigh_pos
) - "fleet_status" (
mavros_msgs/Mavlink
)
- "bvmstate" (
-
Information from the Robot controller (mavros compliant): The node subscribes to:
- "global_position/global" (
sensor_msgs/NavSatFix message
) - "global_position/rel_alt" (
std_msgs/Float64
) - "local_position/pose" (
geometry_msgs/PoseStamped
) - "battery" (
sensor_msgs/BatteryState
) - either "extended_state" (
mavros_msgs/ExtendedState
) or "state" (mavros_msgs/State
)
- "global_position/global" (
-
Messages to Buzz (BVM): The node subscribes to
mavros_msgs/Mavlink
incoming message with name "inMavlink".
- Remote Controller:
The package offers a service "buzzcmd" (
mavros_msgs/CommandLong
) to control it. In the "misc" folder, a bash script shows how to control the swarm state from the command line.
-
[1] ROS and Buzz : consensus-based behaviors for heterogeneous teams. St-Onge, D., Shankar Varadharajan, V., Li, G., Svogor, I. and Beltrame, G. arXiv : https://arxiv.org/abs/1710.08843
-
[2] Over-The-Air Updates for Robotic Swarms. Submitted to IEEE Software (August 2017). 8pgs. Shankar Varadharajan, V., St-Onge, D., Guß, C. and Beltrame, G.
To activate highlights of the code in Visual Studio Code or Roboware add the following to settings.json:
"files.associations": {
"*.bzz":"python"
}