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Hands-On ROS for Robotics Programming

You're reading from   Hands-On ROS for Robotics Programming Program highly autonomous and AI-capable mobile robots powered by ROS

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Product type Paperback
Published in Feb 2020
Publisher Packt
ISBN-13 9781838551308
Length 432 pages
Edition 1st Edition
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Author (1):
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Bernardo Ronquillo Japón Bernardo Ronquillo Japón
Author Profile Icon Bernardo Ronquillo Japón
Bernardo Ronquillo Japón
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Table of Contents (19) Chapters Close

Preface 1. Section 1: Physical Robot Assembly and Testing
2. Assembling the Robot FREE CHAPTER 3. Unit Testing of GoPiGo3 4. Getting Started with ROS 5. Section 2: Robot Simulation with Gazebo
6. Creating the Virtual Two-Wheeled ROS Robot 7. Simulating Robot Behavior with Gazebo 8. Section 3: Autonomous Navigation Using SLAM
9. Programming in ROS - Commands and Tools 10. Robot Control and Simulation 11. Virtual SLAM and Navigation Using Gazebo 12. SLAM for Robot Navigation 13. Section 4: Adaptive Robot Behavior Using Machine Learning
14. Applying Machine Learning in Robotics 15. Machine Learning with OpenAI Gym 16. Achieve a Goal through Reinforcement Learning 17. Assessment 18. Other Books You May Enjoy

Building a differential drive robot with URDF

The GoPiGo3 kit is composed of four several subassemblies:

  • The chassis, which is the main structure that all the parts are attached to. This includes the following:
    • Raspberry Pi and GoPiGo3 board
    • Motors
    • Battery package
    • Wheels
    • Caster
  • Two wheels – left and right, each one driven by one motor.
  • A caster, which is a small freewheel attached to the rear part of the chassis that keeps the robot supported on three points: the left and right wheels and the caster itself. Be aware that one freewheel is the minimum to keep the robot rolling on the floor:
    • If the caster were not present, the system would be underconstrained. Then, you would have a self-balancing robot that would have to be continuously actuated by its motors to stay in equilibrium. This is a closed-loop control problem that needs the Inertial Measurement Unit (IMU)...
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