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Dynamixel Hardware Interface User Guide

1. Introduction

ROS 2 package providing a hardware interface for controlling Dynamixel motors via the ros2_control framework. This repository includes the dynamixel_hardware_interface plugin for seamless integration with ROS 2 control, along with the dynamixel_interfaces package containing custom message definitions used by the interface

2. Prerequisites

ROS 2 Humble

This package currently supports ROS 2 Humble only. Ensure that ROS 2 Humble is properly installed (ROS 2 Humble installation guide).

  • Dynamixel SDK:

    • Install the Dynamixel SDK using the following command:

      sudo apt install ros-humble-dynamixel-sdk
  • Hardware Requirements:

    • Dynamixel servos
    • USB2 Dynamixel or U2D2 adapter
    • Proper power supply for Dynamixel motors

3. Installation

  1. Clone the repository into your ROS workspace:

    cd ~/${WORKSPACE}/src
    git clone -b humble https://github.com/ROBOTIS-GIT/dynamixel_hardware_interface.git
    git clone -b humble https://github.com/ROBOTIS-GIT/dynamixel_interfaces.git
  2. Build the package:

    cd ~/${WORKSPACE}
    colcon build
  3. Source your workspace:

    source ~/${WORKSPACE}/install/setup.bash

4. Currently Used Packages

This project integrates with the following ROS 2 packages to provide extended functionality:

  • open_manipulator_x A ROS-based open-source software package designed for the Open Manipulator-X, a 4-DOF robotic arm. It provides essential features like motion planning, kinematics, and control utilities for seamless integration with ROS 2 environments.

  • open_manipulator_y A ROS-based package tailored for the Open Manipulator-Y, a 6-DOF robotic arm. This package offers enhanced compatibility and extended functionalities for advanced manipulator control and operations.

5. Configuration

To effectively use the Dynamixel Hardware Interface in a ROS 2 control system, you need to configure specific parameters in your ros2_control hardware description file. Below is a concise explanation of the key parameters, illustrated with examples from the OpenManipulator-X ROS 2 control.xacro file.

  1. Port Settings: Define serial port and baud rate for communication.
  2. Hardware Setup: Configure joints and transmissions.
  3. Joints: Control and monitor robot joints.
  4. GPIO: Define and control Dynamixel motors.

1. Port and Communication Settings

These parameters define how the interface communicates with the Dynamixel motors:

  • port_name: Serial port for communication.

  • baud_rate: Communication baud rate.

  • error_timeout_sec: Timeout for communication errors.

2. Hardware Configuration

These parameters define the hardware setup:

  • number_of_joints: Total number of joints.

  • number_of_transmissions: Number of transmissions.

  • Transmission Matrices: Define joint-to-transmission mappings.

3. Joint Configuration

Joints define the control and state interfaces for robot movement:

Key Attributes
  • name: Unique joint name. Example: ${prefix}joint1
Sub-Elements
  1. <command_interface>: Sends commands to joints.

    <command_interface name="position">
  2. <state_interface>: Monitors joint state data.

    <state_interface name="position"/>
    <state_interface name="velocity"/>
    <state_interface name="effort"/>

4. GPIO Configuration

The GPIO tag is used to define the configuration of Dynamixel motors in a robotics system. It serves as a declarative structure to set up motor-specific parameters, command interfaces, and state monitoring capabilities. This allows seamless integration of Dynamixel hardware with software frameworks.

Key Attributes
  • name: A unique identifier for the motor configuration (e.g., dxl1).
  • ID: The unique ID assigned to the motor in the Dynamixel network (e.g., 11).
Sub-Elements
  1. <param>: Specifies motor-specific settings. These parameters correspond to the properties of the Dynamixel motor, such as its type, control mode, or PID gain values.

    <param name="type">dxl</param>
    
  2. <command_interface>: Defines the control commands that can be sent to the motor. For example, setting the desired goal position.

    <command_interface name="Goal Position"/>
    
  3. <state_interface>: Specifies the state feedback interfaces to monitor real-time motor data, such as position, velocity, and current.

    <state_interface name="Present Position"/>
    <state_interface name="Present Velocity"/>
    <state_interface name="Present Current"/>
    
Example GPIO Configuration

Below is an example of a fully defined GPIO configuration for a Dynamixel motor. This example demonstrates how to configure a motor with ID 11, define command interfaces, monitor state data, and set additional parameters such as PID gains and drive mode.

<gpio name="dxl1">
  <param name="type">dxl</param>
  <param name="ID">11</param>
  <command_interface name="Goal Position"/>
  <state_interface name="Present Position"/>
  <state_interface name="Present Velocity"/>
  <state_interface name="Present Current"/>
  <param name="Position P Gain">800</param> <!-- Proportional gain for position control -->
  <param name="Position I Gain">100</param> <!-- Integral gain for position control -->
  <param name="Position D Gain">100</param> <!-- Derivative gain for position control -->
  <param name="Drive Mode">0</param> <!-- 0: Clockwise, 1: Counterclockwise -->
</gpio>
Dynamixel Control Table Reference

The Dynamixel hardware interface uses control tables, defined in model-specific files such as xm430_w350.model, to configure and interact with the motor's internal settings. These control tables map hardware parameters to specific memory addresses and data types, enabling fine-grained control and monitoring.

Example from xm430_w350.model:

[Control Table]
Address   Size    Data Name
0         2       Model Number
2         4       Model Information
6         1       Firmware Version
7         1       ID
...
Usage
  • The control table specifies the internal memory layout of the Dynamixel motor.
  • For instance, you can set the motor ID at address 7, or configure firmware-specific options at address 6.

These settings can be defined within the GPIO configuration or dynamically updated through commands based on the control table schema.

This professional explanation highlights the flexibility and precision of the Dynamixel hardware interface, empowering developers to fully utilize their motor's capabilities within a structured framework. For further details, refer to the official Dynamixel e-Manual.

6. Usage

Ensure the parameters are configured correctly in your ros2_control YAML file or XML launch file.

  • Example Parameter Configuration

    <ros2_control>
        <param name="dynamixel_state_pub_msg_name">dynamixel_hardware_interface/dxl_state</param>
        <param name="get_dynamixel_data_srv_name">dynamixel_hardware_interface/get_dxl_data</param>
        <param name="set_dynamixel_data_srv_name">dynamixel_hardware_interface/set_dxl_data</param>
        <param name="reboot_dxl_srv_name">dynamixel_hardware_interface/reboot_dxl</param>
        <param name="set_dxl_torque_srv_name">dynamixel_hardware_interface/set_dxl_torque</param>
    </ros2_control>

Topic and Service Descriptions

1. dynamixel_state_pub_msg_name
  • Description: Defines the topic name for publishing the Dynamixel state.

  • Default Value: dynamixel_hardware_interface/dxl_state

2. get_dynamixel_data_srv_name
  • Description: Specifies the service name for retrieving Dynamixel data.

  • Default Value: dynamixel_hardware_interface/get_dxl_data

3. set_dynamixel_data_srv_name
  • Description: Specifies the service name for setting Dynamixel data.

  • Default Value: dynamixel_hardware_interface/set_dxl_data

4. reboot_dxl_srv_name
  • Description: Specifies the service name for rebooting Dynamixel motors.

  • Default Value: dynamixel_hardware_interface/reboot_dxl

5. set_dxl_torque_srv_name
  • Description: Specifies the service name for enabling or disabling torque on Dynamixel motors.

  • Default Value: dynamixel_hardware_interface/set_dxl_torque

7. Contributing

We welcome contributions! Please follow the guidelines in CONTRIBUTING.md to submit issues or pull requests.

8. License

This project is licensed under the MIT License. See the LICENSE file for details.