This example shows how to use a TurtleBot® with Vector Field Histograms (VFH) to perform obstacle avoidance when driving a robot in an environment. The robot wanders by driving forward until obstacles get in the way. The
robotics.VectorFieldHistogram class computes steering directions to avoid objects while trying to drive forward.
Optional: If you do not already have a TurtleBot (simulated or real) set up, install a virtual machine with the Gazebo simulator and TurtleBot package. See Get Started with Gazebo and a Simulated TurtleBot to install and set up a TurtleBot in Gazebo.
Connect to the TurtleBot using the IP address obtained from setup.
Initializing global node /matlab_global_node_96529 with NodeURI http://192.168.203.1:60914/
Create a publisher and subscriber to share information with the VFH class. The subscriber receives the laser scan data from the robot. The publisher sends velocity commands to the robot.
The topics used are for the simulated TurtleBot. Adjust the topic names for your specific robot.
laserSub = rossubscriber('/scan'); [velPub, velMsg] = rospublisher('/mobile_base/commands/velocity');
Set up VFH object for obstacle avoidance. Specify algorithm properties for robot specifications. Set target direction to
0 in order to drive straight.
vfh = robotics.VectorFieldHistogram; vfh.DistanceLimits = [0.05 1]; vfh.RobotRadius = 0.1; vfh.MinTurningRadius = 0.2; vfh.SafetyDistance = 0.1; targetDir = 0;
Set up a Rate object using
robotics.Rate, which can track the timing of your loop. This object can be used to control the rate the loop operates as well.
rate = robotics.Rate(10);
Create a loop that collects data, calculates steering direction, and drives the robot. Set a loop time of 30 seconds.
Use the ROS subscriber to collect laser scan data. Calculate the steering direction with the VFH object based on the input laser scan data. Convert the steering direction to a desired linear and an angular velocity. If a steering direction is not found, the robot stops and searches by rotating in place.
Drive the robot by sending a message containing the angular velocity and the desired linear velocity using the ROS publisher.
while rate.TotalElapsedTime < 30 % Get laser scan data laserScan = receive(laserSub); ranges = double(laserScan.Ranges); angles = double(laserScan.readScanAngles); % Call VFH object to computer steering direction steerDir = vfh(ranges, angles, targetDir); % Calculate velocities if ~isnan(steerDir) % If steering direction is valid desiredV = 0.2; w = exampleHelperComputeAngularVelocity(steerDir, 1); else % Stop and search for valid direction desiredV = 0.0; w = 0.5; end % Assign and send velocity commands velMsg.Linear.X = desiredV; velMsg.Angular.Z = w; velPub.send(velMsg); end
This code shows how you can use the Robotics System Toolbox™ algorithms to control robots and react to dynamic changes in their environment. Currently the loop ends after 30 seconds, but other conditions can be set to exit the loop based on information on the ROS network (i.e. robot position or number of laser scan messages).
Disconnect from the ROS network
Shutting down global node /matlab_global_node_96529 with NodeURI http://192.168.203.1:60914/