This example shows how to simulate a warehouse robot in Gazebo. Gazebo enabled you to simulate a mobile robot that uses a range sensor, while executing certain tasks in a simulated environment. This example details how to use a simulator to apply the Execute Tasks for a Warehouse Robot example, where a robot delivers packages in a warehouse scenario. The robot makes use of the simulated range sensor in Gazebo to detect possible collisions with a dynamic environment and avoid them.
Download a Virtual Machine with ROS and Gazebo to set up a simulated robot.
Review the Execute Tasks for a Warehouse Robot example for the workflow of path planning and navigating in a warehouse scenario.
Review the Control a Differential Drive Robot in Gazebo with Simulink example for basic steps of collecting sensor data and controlling a robot in Gazebo.
Open the model.
The model can be divided into the following elements:
Sense: Read data from sensors in Gazebo.
Schedule: Assign packages and plan paths for robots to deliver the packages.
Control: Generate commands to follow the predefined path and avoid obstacles.
Actuate: Send commands to Gazebo to actuate the robot in the environment.
The robot performs the task of going between the charging station, the loading station, and the unloading station as guided by the Scheduler.
The current robot pose, the wheel speeds, and the range sensor readings are read from the simulated environment in Gazebo. The figure below is the expanded view of the Read From Gazebo Sensors subsystem.
The controller generates control commands for following the waypoints using the Pure Pursuit block. If the range sensor on the robot detects an obstacle within the
avoidCollisionDistance threshold, the robot stops. Also, the robot stops when gets near enough to the goal.
Based on the generated control commands, the Pioneer Wheel Control subsystem generates a torque value for each wheel.The torque is applied as an
Load the example map file,
map, which is a matrix of logical values indicating occupied space in the warehouse. Invert this matrix to indicate free space, and make a
binaryOccupancyMap object. Specify a resolution of 100 cells per meter.
The map is based off of the
warehouseExtensions.world file, which was made using the Building Editor on the same scaling factor as mentioned below. A
.png file for the map can be made using the
collision_map_creator_plugin plugin to generate the map matrix. The details on how to install the plugin can be found at Collision Map Creator Plugin.
mapScalingFactor = 100; load gazeboWarehouseMap.mat map logicalMap = ~map; map = binaryOccupancyMap(logicalMap,mapScalingFactor); show(map)
Assign the xy-locations of the charging station, sorting station, and the unloading location near shelves in the warehouse. The values chosen are based on the simlated world in Gazebo.
chargingStn = [12,5]; loadingStn = [24,5]; unloadingStn = [15,24];
Show the various locations on the map.
hold on; text(chargingStn(1), chargingStn(2), 1, 'Charging'); plotTransforms([chargingStn, 0], [1 0 0 0]) text(loadingStn(1), loadingStn(2), 1, 'Sorting Station'); plotTransforms([loadingStn, 0], [1 0 0 0]) text(unloadingStn(1), unloadingStn(2), 1, 'Unloading Station'); plotTransforms([unloadingStn, 0], [1 0 0 0]) hold off;
The Read Lidar Scan block in the Sensing section is used to read the range values from the simulated range sensor. The
warehouseExtensions.world file contains the details of the various models and actors (warehouse workers) in the scene. Because <
actor> tags are static links with only visual meshes, the sensor type of the range sensor is
Additionally, the range sensor uses 640 range, but the default is 128. This requires modification of the buses used in the in the Read Lidar Scan block. Load the
exampleHelperWarehouseRobotWithGazeboBuses.mat file to get a modified bus with
Gazebo_SL_Bus_gazebo_msgs_LaserScan.range set to 640. The modified buses were saved to a
.mat file using the Bus Editor.
The actors in the world are walking a predefined trajectory. The robot makes use of a range sensor to check for obstacles within a range of 2.0 m (
avoidCollisionDistance) with range angles from
[-pi/10, pi/10] Upon a non-zero reading within that range and view, the robot stops and only resumes after the range is clear. The "Stop Robot On Sensing Obstacles" function block incorporates this logic.
While running the simulation, the Stop lamp turns green when the robot senses that it is good to proceed. If it has stopped the lamp turns red.
avoidCollisionDistance = 2;
To simulate the scenario, set up the connection to Gazebo.
First, run the Gazebo Simulator. In the virtual machine, click the Gazebo Warehouse Robot icon. If the Gazebo simulator fails to open, you may need to reinstall the plugin. See Install Gazebo Plugin Manually in Perform Co-Simulation between Simulink and Gazebo.
In Simulink, open the Gazebo Pacer block and click Configure Gazebo network and simulation settings. Specify the Network Address as Custom, the Hostname/IP Address for your Gazebo simulation, and a Port of
14581, which is the default port for Gazebo. The desktop of the VM displays the IP address.
For more information about connecting to Gazebo to enable co-simulation, see Perform Co-Simulation between Simulink and Gazebo.
Click the Initialize Model button at the top of the model to intialize all the variables declared above.
Run the simulation. The robot drives around the environment and stops whenever a worker gets within the defined threshold.