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Warning! This version of documentation is OUTDATED, as it describes an older SDK version! Please switch to the documentation for the latest SDK version.
Warning! This version of documentation describes an old SDK version which is no longer supported! Please upgrade to the latest SDK version.

ROS Vehicle


There are multiple types of robots from vacuum cleaners to autonomous combine harvesters, drones etc. Most of them are made of actuators (things that move), sensors (things that read the world), and control systems (robot's brain) There is a way to simplify the complex process of making these components work together - Robot Operating System (ROS), which is a set of free and open-source software libraries and tools that help you build robot applications. ROS enables you to quickly build components and easily connect them via messages. These messages can be sent to various visualization or teleoperation tools so you can work with a simulated robot (digital twin) instead of the real thing. Thus, with ROS you can build complex distributed systems with multiple nodes for different tasks (controls, image generation, etc.), it supports hardware interfaces for many common robot components like motor controllers, LiDARS, and cameras. The whole framework enables you to focus on implementing your logic, not reinventing the wheel. The list of tasks that can be effectively solved using ROS includes logging and diagnostics, fleet management, deep learning data collection (training), testing & quality assurance, and a lot more.

This demo is based on ROS2 Galactic and showcases integration of the Robot Operating System (ROS 2) with a UNIGINE project to help build robot applications. The demo implements simulation of the automotive vehicle control via ROS and simulation of sensors (cameras and LiDARs) mounted on the car. In the application, you can control two vehicles available in the demo scene. The data from cameras and LiDARs can be sent via ROS to any other listening app.

Notice
The ROS Vehicle project can't be built in Visual Studio or CMake. Use this instruction to build the project.

Features#

This demo requires at least two modules (ROS nodes) to be run simultaneously:

  • ROS Vehicle (Simulator) — renders the simulation and sensor data that can be sent via ROS to any other listening app and simulates physics (UNIGINE can also be used as Image Generator with physics and vehicle model calculated on separate nodes). Use WASD controls + mouse to move the overall view camera. To control the vehicles, use Teleop applications, the Simulator shall receive user input and move vehicles accordingly.
  • ROS Control (Teleop) — processes the input (control keys pressed) from the user and transmits it to other ROS nodes. To control two vehicles simultaneously, you can run two Teleop applications on the same PC or on different PCs in the local network. Another control application (e.g. your own implementation of control system of an autonomous vehicle) can be used instead of Teleop to control vehicles in the Simulator.

The Simulator application sends data from cameras and LiDARs to RViz 3D visualization tool for ROS (included in the original ROS2 package) that renders point cloud visualization based on the sensor data received.

To launch RViz 3D application use the corresponding script depending on your OS: run_rviz2_linux.sh/run_rviz2_windows.bat.

Workflow#

The simplified workflow of implementing a robot system using new ROS integration in UNIGINE is as follows:

  1. Design your robot, define all sensors and actuators.
  2. Implement your robot's control system.
  3. Create a 3D model and implement an entity for your robot in UNIGINE (and other entities if necessary).
  4. Connect your control system instead of the Teleop node.
  5. Connect RViz 3D or other visualization tools to process and display the data from robot's sensors.

In this case you just concentrate on your task - development of control system and implementation of a digital twin for your robot, without having to think about data transmission or write other utility code.

System Requirements#

Requirements for ROS2 Galactic are the following:

  • Operating system:

    • MS Windows 10 x64
    • Ubuntu Linux - Focal Fossa (20.04)
  • Python 3 (3.8-3.10)
    Notice
    On Windows, you should add a path to python.exe to the PATH environment variable after installation.
    • Required packages for Python 3:

      Shell commands
      python3 -m pip install lark
      python3 -m pip install numpy
      python3 -m pip install -U colcon-common-extensions

Additional Requirements for Development#

  • Qt 5.12.x
  • MS Visual Studio 2022 on Windows
  • CMake on Linux
    Shell commands
    sudo apt install gcc g++ cmake

MATLAB Integration Sample#

The demo provides a MATLAB script that implements a vehicle that drives between two points. This script receives telemetry data from the vehicle, processes it, and then sends control commands to this vehicle.

Notice
MATLAB Integration is currently available for Windows only.

Before running the sample, make sure you have installed:

  • Python 3 (3.8-3.10). You also need to add a path to python.exe to the PATH environment variable.
  • MATLAB with ROS Toolbox. This option is available during the installation process.

To run the sample on Windows, perform the following:

  1. Launch the demo and open the ROS Vehicle sample.
  2. Run the matlab_ros_sample.m MATLAB script and wait for the build to complete.
    Notice
    You might receive a request to delete the C:/Users/user/source folder.

The vehicle will then start driving on the lake between two points hardcoded in the MATLAB script.


SDK Path: <SDK_INSTALLATION>demos\ros_demo_2.19

Accessing Demo Source Code#

You can study and modify the source code of this demo to create your own projects. To access the source code do the following:

  1. Find the ROS Vehicle demo in the Demos section and click Install (if you haven't installed it yet).
  2. After successful installation the demo will appear in the Installed section, and you can click Copy as Project to create a project based on this demo.
  3. In the Create New Project window, that opens, enter the name for your new project in the corresponding field and click Create New Project.
  4. Now you can click Open Code IDE to check and modify source code in your default IDE, or click Open Editor to open the project in the UnigineEditor.
Last update: 2024-08-16
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