Skip to content

Latest commit

 

History

History
66 lines (42 loc) · 3.83 KB

README.md

File metadata and controls

66 lines (42 loc) · 3.83 KB

Overview

stretch_navigation provides the standard ROS navigation stack as two launch files. This package utilizes gmapping, move_base, and AMCL to drive the stretch RE1 around a mapped space. Running this code will require the robot to be untethered.

Quickstart

The first step is to map the space that the robot will navigate in. The mapping.launch will enable you to do this. First run:

roslaunch stretch_navigation mapping.launch

Rviz will show the robot and the map that is being constructed. With the terminal open, use the instructions printed by the teleop package to teleoperate the robot around the room. Avoid sharp turns and revisit previously visited spots to form loop closures. In Rviz, once you see a map that has reconstructed the space well enough, you can run the following commands to save the map to stretch_user/.

mkdir -p ~/stretch_user/maps
rosrun map_server map_saver -f ${HELLO_FLEET_PATH}/maps/<map_name>

The <map_name> does not include an extension. Map_saver will save two files as <map_name>.pgm and <map_name>.yaml.

Next, with <map_name>.yaml, we can navigate the robot around the mapped space. Run:

roslaunch stretch_navigation navigation.launch map_yaml:=${HELLO_FLEET_PATH}/maps/<map_name>.yaml

Rviz will show the robot in the previously mapped space, however, it's likely that the robot's location in the map does not match the robot's location in the real space. In the top bar of Rviz, use 2D Pose Estimate to lay an arrow down roughly where the robot is located in the real space. AMCL, the localization package, will better localize our pose once we give the robot a 2D Nav Goal. In the top bar of Rviz, use 2D Nav Goal to lay down an arrow where you'd like the robot to go. In the terminal, you'll see move_base go through the planning phases and then navigate the robot to the goal. If planning fails, the robot will begin a recovery behavior: spinning around 360 degrees in place.

It is also possible to send 2D Pose Estimates and Nav Goals programatically. In your own launch file, you may include navigation.launch to bring up the navigation stack. Then, you can send move_base_msgs::MoveBaseGoal messages in order to navigate the robot programatically.

Running in Simulation

To perform mapping and navigation in the Gazebo simulation of Stretch, substitute the mapping_gazebo.launch and navigation_gazebo.launch launch files into the commands above. The default Gazebo environment is the Willow Garage HQ. Use the "world" ROS argument to specify the Gazebo world within which to spawn Stretch.

roslaunch stretch_navigation mapping_gazebo.launch gazebo_world:=worlds/willowgarage.world

Teleop using a Joystick Controller

The mapping launch files, mapping.launch and mapping_gazebo.launch expose the ROS argument, "teleop_type". By default, this ROS arg is set to "keyboard", which launches keyboard teleop in the terminal. If the xbox controller that ships with Stretch RE1 is plugged into your computer, the following command will launch mapping with joystick teleop:

roslaunch stretch_navigation mapping.launch teleop_type:=joystick

Using ROS Remote Master

If you have set up ROS Remote Master for untethered operation, you can use Rviz and teleop locally with the following commands:

# On Robot
roslaunch stretch_navigation mapping.launch rviz:=false teleop_type:=none

# On your machine, Terminal 1:
rviz -d `rospack find stretch_navigation`/rviz/mapping.launch
# On your machine, Terminal 2:
roslaunch stretch_core teleop_twist.launch teleop_type:=keyboard # or use teleop_type:=joystick if you have a controller

License

For license information, please see the LICENSE files.