Show EOL distros: 

ros_controllers: diff_drive_controller | effort_controllers | force_torque_sensor_controller | forward_command_controller | gripper_action_controller | imu_sensor_controller | joint_state_controller | joint_trajectory_controller | position_controllers | velocity_controllers

Package Summary

Controller for a differential drive mobile base.

ros_controllers: diff_drive_controller | effort_controllers | force_torque_sensor_controller | forward_command_controller | gripper_action_controller | imu_sensor_controller | joint_state_controller | joint_trajectory_controller | position_controllers | rqt_joint_trajectory_controller | velocity_controllers

Package Summary

Controller for a differential drive mobile base.

ros_controllers: ackermann_steering_controller | diff_drive_controller | effort_controllers | force_torque_sensor_controller | forward_command_controller | gripper_action_controller | imu_sensor_controller | joint_state_controller | joint_trajectory_controller | position_controllers | rqt_joint_trajectory_controller | velocity_controllers

Package Summary

Controller for a differential drive mobile base.

Overview

Controller for differential drive wheel systems. Control is in the form of a velocity command, that is split then sent on the two wheels of a differential drive wheel base. Odometry is computed from the feedback from the hardware, and published.

Velocity commands

The controller works with a velocity twist from which it extracts the x component of the linear velocity and the z component of the angular velocity. Velocities on other components are ignored.

Hardware interface type

The controller works with wheel joints through a velocity interface.

Other features

  • Realtime-safe implementation.

  • Odometry publishing
  • Task-space velocity, acceleration and jerk limits
  • Automatic stop after command time-out

Mathematical Background

https://upload.wikimedia.org/wikipedia/commons/2/28/Differential_Drive_Kinematics_of_a_Wheeled_Mobile_Robot.svg

The illustration on the right shows a sketch of a differential drive wheeled robot. In this sketch, the following notation applies.

  • https://latex.codecogs.com/svg.image?V - linear velocity (Velocity Command, see chapter 1.1)

  • https://latex.codecogs.com/svg.image?\omega - angular velocity by which the robot rotates (Velocity Command, see chapter 1.1)

  • https://latex.codecogs.com/svg.image?X and https://latex.codecogs.com/svg.image?Y - global coordinate system

  • https://latex.codecogs.com/svg.image?X_{B} and https://latex.codecogs.com/svg.image?Y_{B} - locale body coordinate system

  • https://latex.codecogs.com/svg.image?\varphi - angle of robot with respect to global coordinate system

  • https://latex.codecogs.com/svg.image?r - radius of the wheels

  • https://latex.codecogs.com/svg.image?b - width of the vehicle

  • https://latex.codecogs.com/svg.image?ICR⁣ - instantaneous center of rotation

  • https://latex.codecogs.com/svg.image?v_{L}, https://latex.codecogs.com/svg.image?v_{R} - ground contact speed of left and right wheel

  • https://latex.codecogs.com/svg.image?\omega_{L}, https://latex.codecogs.com/svg.image?\omega_{R} - angular velocity of left and right wheel

Using the kinematic model (see here), the diff_drive_controller calculates the left https://latex.codecogs.com/svg.image?\omega_{L} and right angular velocity https://latex.codecogs.com/svg.image?\omega_{R} to:

https://latex.codecogs.com/svg.image?\omega_{L}&space;=&space;\frac{V-\omega&space;\cdot&space;b/2}{r}

and

https://latex.codecogs.com/svg.image?\omega_{R}&space;=&space;&space;&space;\frac{V+\omega&space;\cdot&space;b/2}{r}.

Robots

REEM

PAL Robotics REEM

PMB2

PAL Robotics Mobile Base

Husky

Clearpath Robotics Husky

Robots/Jackal

Clearpath Robotics Jackal

i-Cart mini

i-Cart mini

Remo

ros-mobile-robots/diffbot

ROS API

Description

The controller main input is a geometry_msgs::Twist topic in the namespace of the controller.

Subscribed Topics

cmd_vel (geometry_msgs/Twist)
  • Velocity command.

Published Topics

odom (nav_msgs/Odometry)
  • Odometry computed from the hardware feedback.
/tf (tf/tfMessage)
  • Transform from odom to base_footprint
publish_cmd (geometry_msgs/TwistStamped)
  • Available when "publish_cmd" parameter is set to True. It is the Twist after limiters have been applied on the controller input.

Parameters

left_wheel (string | string[...])
  • Left wheel joint name or list of joint names
right_wheel (string | string[...])
  • Right wheel joint name or list of joint names
pose_covariance_diagonal (double[6])
  • Diagonal of the covariance matrix for odometry pose publishing
twist_covariance_diagonal (double[6])
  • Diagonal of the covariance matrix for odometry twist publishing
publish_rate (double, default: 50.0)
  • Frequency (in Hz) at which the odometry is published. Used for both tf and odom
wheel_separation_multiplier (double, default: 1.0)
  • Multiplier applied to the wheel separation parameter. This is used to account for a difference between the robot model and a real robot.
wheel_radius_multiplier (double, default: 1.0)
  • Multiplier applied to the wheel radius parameter. This is used to account for a difference between the robot model and a real robot.
cmd_vel_timeout (double, default: 0.5)
  • Allowed period (in s) allowed between two successive velocity commands. After this delay, a zero speed command will be sent to the wheels.
base_frame_id (string, default: base_link)
  • Base frame_id, which is used to fill in the child_frame_id of the Odometry messages and TF.
linear/x/has_velocity_limits (bool, default: false)
  • Whether the controller should limit linear speed or not.
linear/x/max_velocity (double)
  • Maximum linear velocity (in m/s)
linear/x/min_velocity (double)
  • Minimum linear velocity (in m/s). Setting this to 0.0 will disable backwards motion. When unspecified, -max_velocity is used.
linear/x/has_acceleration_limits (bool, default: false)
  • Whether the controller should limit linear acceleration or not.
linear/x/max_acceleration (double)
  • Maximum linear acceleration (in m/s^2)
linear/x/min_acceleration (double)
  • Minimum linear acceleration (in m/s^2). When unspecified, -max_acceleration is used.
linear/x/has_jerk_limits (bool, default: false)
  • Whether the controller should limit linear jerk or not.
linear/x/max_jerk (double)
  • Maximum linear jerk (in m/s^3).
angular/z/has_velocity_limits (bool, default: false)
  • Whether the controller should limit angular velocity or not.
angular/z/max_velocity (double)
  • Maximum angular velocity (in rad/s)
angular/z/min_velocity (double)
  • Minimum angular velocity (in rad/s). Setting this to 0.0 will disable counter-clockwise rotation. When unspecified, -max_velocity is used.
angular/z/has_acceleration_limits (bool, default: false)
  • Whether the controller should limit angular acceleration or not.
angular/z/max_acceleration (double)
  • Maximum angular acceleration (in rad/s^2)
angular/z/min_acceleration (double)
  • Minimum angular acceleration (in rad/s^2). When unspecified, -max_acceleration is used.
angular/z/has_jerk_limits (bool, default: false)
  • Whether the controller should limit angular jerk or not.
angular/z/max_jerk (double)
  • Maximum angular jerk (in m/s^3).
enable_odom_tf (bool, default: true)
  • Publish to TF directly or not
wheel_separation (double)
  • The distance of the left and right wheel(s). The diff_drive_controller will attempt to read the value from the URDF if this parameter is not specified
wheel_radius (double)
  • Radius of the wheels. It is expected they all have the same size. The diff_drive_controller will attempt to read the value from the URDF if this parameter is not specified.
odom_frame_id (string, default: "/odom")
  • Name of frame to publish odometry in.
publish_cmd (bool, default: False)
  • Publish the velocity command to be executed. It is to monitor the effect of limiters on the controller input.
allow_multiple_cmd_vel_publishers (bool, default: False)
  • Setting this to true will allow more than one publisher on the input topic, ~/cmd_vel. Setting this to false will cause the controller to brake if there is more than one publisher on ~/cmd_vel.
velocity_rolling_window_size (int, default: 10)
  • The number of velocity samples to average together to compute the odometry twist.linear.x and twist.angular.z velocities

Controller configuration examples

Minimal description

mobile_base_controller:
  type: "diff_drive_controller/DiffDriveController"
  left_wheel: 'wheel_left_joint'
  right_wheel: 'wheel_right_joint'
  pose_covariance_diagonal: [0.001, 0.001, 1000000.0, 1000000.0, 1000000.0, 1000.0]
  twist_covariance_diagonal: [0.001, 0.001, 1000000.0, 1000000.0, 1000000.0, 1000.0]

Complete description

mobile_base_controller:
  type        : "diff_drive_controller/DiffDriveController"
  left_wheel  : 'wheel_left_joint'
  right_wheel : 'wheel_right_joint'
  publish_rate: 50.0               # default: 50
  pose_covariance_diagonal : [0.001, 0.001, 1000000.0, 1000000.0, 1000000.0, 1000.0]
  twist_covariance_diagonal: [0.001, 0.001, 1000000.0, 1000000.0, 1000000.0, 1000.0]

  # Wheel separation and diameter. These are both optional.
  # diff_drive_controller will attempt to read either one or both from the
  # URDF if not specified as a parameter
  wheel_separation : 1.0
  wheel_radius : 0.3

  # Wheel separation and radius multipliers
  wheel_separation_multiplier: 1.0 # default: 1.0
  wheel_radius_multiplier    : 1.0 # default: 1.0

  # Velocity commands timeout [s], default 0.5
  cmd_vel_timeout: 0.25

  # Base frame_id
  base_frame_id: base_footprint #default: base_link

  # Velocity and acceleration limits
  # Whenever a min_* is unspecified, default to -max_*
  linear:
    x:
      has_velocity_limits    : true
      max_velocity           : 1.0  # m/s
      min_velocity           : -0.5 # m/s
      has_acceleration_limits: true
      max_acceleration       : 0.8  # m/s^2
      min_acceleration       : -0.4 # m/s^2
      has_jerk_limits        : true
      max_jerk               : 5.0  # m/s^3
  angular:
    z:
      has_velocity_limits    : true
      max_velocity           : 1.7  # rad/s
      has_acceleration_limits: true
      max_acceleration       : 1.5  # rad/s^2
      has_jerk_limits        : true
      max_jerk               : 2.5  # rad/s^3

Skid steer

The diff_drive_controller allows for skid steer driving with the geometry_msgs/Twist command interface however it doesn't support direct skid commands.

The current implementation allows you to register multiple wheels per side and will average those wheel positions in its odometry calculations. For more info read the code and issue.

Multiple wheels per side example from Jackal.

jackal_velocity_controller:
  type: "diff_drive_controller/DiffDriveController"
  left_wheel: ['front_left_wheel', 'rear_left_wheel']
  right_wheel: ['front_right_wheel', 'rear_right_wheel']
  publish_rate: 50
  pose_covariance_diagonal: [0.001, 0.001, 1000000.0, 1000000.0, 1000000.0, 0.03]
  twist_covariance_diagonal: [0.001, 0.001, 0.001, 1000000.0, 1000000.0, 0.03]
  cmd_vel_timeout: 0.25

  # Odometry fused with IMU is published by robot_localization, so
  # no need to publish a TF based on encoders alone.
  enable_odom_tf: false

  # Wheel separation and radius multipliers
  wheel_separation_multiplier: 1.5 # default: 1.0
  wheel_radius_multiplier    : 1.0 # default: 1.0

  # Velocity and acceleration limits
  # Whenever a min_* is unspecified, default to -max_*
  linear:
    x:
      has_velocity_limits    : true
      max_velocity           : 2.0   # m/s
      has_acceleration_limits: true
      max_acceleration       : 20.0   # m/s^2
  angular:
    z:
      has_velocity_limits    : true
      max_velocity           : 4.0   # rad/s
      has_acceleration_limits: true
      max_acceleration       : 25.0   # rad/s^2

Further reading

In addition to the robots addressed in chapter 2, tutorials for the application of the diff_drive_controller should be briefly mentioned.

A basic understanding of the implementation of ros_control and its interaction with the hardware_interface is explained in this post.

An overview of the diff_drive_controller and its integration into ros_control can be found in the DiffBot Base Package tutorial.

A detailed description of the specific execution and application of the diff_drive_controller can also be found in the DiffBot Base Package.

In the Jackal Robot, the diff_drive_controller is also applied, and the control commands (https://latex.codecogs.com/svg.image?\omega_{L} and https://latex.codecogs.com/svg.image?\omega_{R}) are being retrieved in the hardware_interface and forwarded to the corresponding drives.

Wiki: diff_drive_controller (last edited 2023-04-13 10:10:40 by Dr.No)