• related repo (lang 🇭🇺): robotrendszerek programozása/beadando
• related YouTube video: ROS2 Tutorial - ROS2 Humble 2H50 [Crash Course]
• robotics academy: https://jderobot.github.io/RoboticsAcademy/
• other good ROS tutorials: https://www.theconstructsim.com/

ROS introduction, setting up the development environment. Implement ROS packages in Python. Basic ROS communication, implementing publishers and subscribers. Principles of robotics, programming a simulated robot in joint and workspace. Roslaunch, ROS parameter server. Acquisition and processing of sensory data in ROS. Programming da Vinci surgical robot in simulated environment. Programming humanoid robot. In simulated environment. Define custom messages. ROS service and ROS action.

10 years of ROS: https://www.youtube.com/watch?v=mDwZ21Zia8s

• The ROS toics can handle only one variable type. To get thy type: rosmsg show <topicname>.
• List available ROS message types: rosmsg list
  • a message file extension is .msg
• see current ROS topics: rostopic list
• start ROS: roscore
• record ROS rosbag record --all
• play ROS rosbag play <myfile>.bag
• launch file roslaunch <myfile>
• action files are: .action

• System configuration: https://docs.ros.org/en/foxy/Tutorials/Beginner-CLI-Tools/Configuring-ROS2-Environment.html
• note: ros version depends on ubuntu version!, more: Unable to locate package ros foxy desktop
• A good starting point is the turtlesim

using rqt to:

• change values: https://docs.ros.org/en/humble/Tutorials/Beginner-CLI-Tools/Introducing-Turtlesim/Introducing-Turtlesim.html
• viewlogs: https://docs.ros.org/en/humble/Tutorials/Beginner-CLI-Tools/Using-Rqt-Console/Using-Rqt-Console.html

A node is a fundamental ROS 2 element that serves a single, modular purpose in a robotics system.

The ROS graph is a network of ROS 2 elements processing data together at one time. It encompasses all executables and the connections between them if you were to map them all out and visualize them.

Each node in ROS should be responsible for a single, module purpose (e.g. one node for controlling wheel motors, one node for controlling a laser range-finder, etc). Each node can send and receive data to other nodes via topics, services, actions, or parameters.

• list node names: ros2 node list
• to reassign default node properties, like node name, topic names, service names, etc., to custom values use remapping: --remap, example: ros2 run turtlesim turtlesim_node --ros-args --remap __node:=my_turtle
• get information about the node: ros2 node info <node_name>

tutorial with turtlesim: https://docs.ros.org/en/humble/Tutorials/Beginner-CLI-Tools/Understanding-ROS2-Nodes/Understanding-ROS2-Nodes.html#ros2-node-list

Topics are one of the main ways in which data is moved between nodes and therefore between different parts of the system. Nodes send data over topics using messages. Publishers and subscribers must send and receive the same type of message to communicate.

ROS 2 breaks complex systems down into many modular nodes. Topics are a vital element of the ROS graph that act as a bus for nodes to exchange messages.	A node may publish data to any number of topics and simultaneously have subscriptions to any number of topics.

• to visualise current topic subscriptions on nodes: rqt_graph
• command line tools:
  • list of all the topics currently active in the system: ros2 topic list
  • list of all the topics type appended in brackets:ros2 topic list -t
• see the data being published on a topic: ros2 topic echo <topic_name> this command won’t return any data. That’s because it’s waiting for <topic_name> to publish something.
• see how many publishers/subscriptions are on the topic: ros2 topic info <topic_name>
• to learn what structure of data the message expects: ros2 interface show <msg type>
• publish data onto a topic directly from the command line using: ros2 topic pub <topic_name> <msg_type> '<args>'
  • this argument needs to be input in YAML syntax, ex: ros2 topic pub --once /turtle1/cmd_vel geometry_msgs/msg/Twist "{linear: {x: 2.0, y: 0.0, z: 0.0}, angular: {x: 0.0, y: 0.0, z: 1.8}}"
  • argument to publish one message then exit: --once
  • to publish the command in a steady stream at 1 Hz use --rate 1 option, ex: ros2 topic pub --rate 1 /turtle1/cmd_vel geometry_msgs/msg/Twist "{linear: {x: 2.0, y: 0.0, z: 0.0}, angular: {x: 0.0, y: 0.0, z: 1.8}}"
• view the rate at which data is published: ros2 topic hz <topic_name>

tutorial with turtlesim: https://docs.ros.org/en/foxy/Tutorials/Beginner-CLI-Tools/Understanding-ROS2-Topics/Understanding-ROS2-Topics.html#tasks

Services are another method of communication for nodes in the ROS graph. Services are based on a call-and-response model, versus topics’ publisher-subscriber model. While topics allow nodes to subscribe to data streams and get continual updates, services only provide data when they are specifically called by a client.

Services have types that describe how the request and response data of a service is structured. Service types are defined similarly to topic types, except service types have two parts: one message for the request and another for the response.

Nodes can communicate using services in ROS 2. Unlike a topic - a one way communication pattern where a node publishes information that can be consumed by one or more subscribers - a service is a request/response pattern where a client makes a request to a node providing the service and the service processes the request and generates a response.

You generally don’t want to use a service for continuous calls; topics or even actions would be better suited.

• a list of all the services currently active in the system: ros2 service list
• type of a service: ros2 service type <service_name>
  • service call sends no data when making a request and receives no data when receiving a response: Empty
• see the types of all the active services: ros2 service list -t
  • you can append the option: --show-types, -t, list
• all the services of a specific type: ros2 service find <type_name>
• to know the structure of the input arguments: ros2 interface show <type_name>.srv
• call a service: ros2 service call <service_name> <service_type> <arguments>. Note: The <arguments> part is optional. ex: ros2 service call /clear std_srvs/srv/Empty

tutorial with turtlesim: https://docs.ros.org/en/humble/Tutorials/Beginner-CLI-Tools/Understanding-ROS2-Services/Understanding-ROS2-Services.html#tasks

A parameter is a configuration value of a node. You can think of parameters as node settings. A node can store parameters as integers, floats, booleans, strings, and lists. In ROS 2, each node maintains its own parameters. more...

Nodes have parameters to define their default configuration values. You can get and set parameter values from the command line. You can also save the parameter settings to a file to reload them in a future session.

• see the parameters belonging to your nodes: ros2 param list
  • Every node has the parameter use_sim_time
• display the type and current value of a parameter: ros2 param get <node_name> <parameter_name> ex: ros2 param get /turtlesim background_g
• change a parameter’s value at runtime: ros2 param set <node_name> <parameter_name> <value>
• view all of a node’s current parameter values: ros2 param dump <node_name> Dumping parameters comes in handy if you want to reload the node with the same parameters in the future.
• load parameters from a file to a currently running node: ros2 param load <node_name> <parameter_file>
• start the same node using your saved parameter values: ros2 run <package_name> <executable_name> --ros-args --params-file <file_name>

tutorial based on turtlesim: https://docs.ros.org/en/humble/Tutorials/Beginner-CLI-Tools/Understanding-ROS2-Parameters/Understanding-ROS2-Parameters.html#tasks

Actions are one of the communication types in ROS 2 and are intended for long running tasks. They consist of three parts: a goal, feedback, and a result.

Actions are built on topics and services. Their functionality is similar to services, except actions can be canceled. They also provide steady feedback, as opposed to services which return a single response.

Actions use a client-server model, similar to the publisher-subscriber model. An “action client” node sends a goal to an “action server” node that acknowledges the goal and returns a stream of feedback and a result. Actions have types, similar to topics and services.

Not only can the client-side (your input in the teleop) stop a goal, but the server-side can as well. When the server-side chooses to stop processing a goal, it is said to “abort” the goal.

Actions are like services that allow you to execute long running tasks, provide regular feedback, and are cancelable.

A robot system would likely use actions for navigation. An action goal could tell a robot to travel to a position. While the robot navigates to the position, it can send updates along the way (i.e. feedback), and then a final result message once it’s reached its destination.

This action server chose to abort the first goal because it got a new one. It could have chosen something else, like reject the new goal or execute the second goal after the first one finished. Don’t assume every action server will choose to abort the current goal when it gets a new one.

• see node’s actions: ros2 node info /<node_name>
• identify all the actions in the ROS graph, run the command: ros2 action list
• find actions's type: ros2 action list -t In brackets to the right of each action name is the action type. You will need this when you want to execute an action from the command line or from code.
• You can further introspect the action: ros2 action info /<action_name> this will list clients and servers
• the structure of the action type: ros2 interface show <interface_name> the detailed description of the values in the action
• send an action goal from the command line: ros2 action send_goal <action_name> <action_type> <values> ex: ros2 action send_goal /turtle1/rotate_absolute turtlesim/action/RotateAbsolute "{theta: 1.57}"

tutorial based on turtlesim: https://docs.ros.org/en/humble/Tutorials/Beginner-CLI-Tools/Understanding-ROS2-Actions/Understanding-ROS2-Actions.html#tasks

Launch files allow you to start up and configure a number of executables containing ROS 2 nodes simultaneously. Running a single launch file with the ros2 launch command will start up your entire system - all nodes and their configurations - at once.

Launch files caould be written in Python or in XML, YAML

more about launch files: https://docs.ros.org/en/humble/Tutorials/Intermediate/Launch/Launch-Main.html

Once you learn to write your own launch files, you’ll be able to run multiple nodes - and setup their configuration

• start ros2 packages: ros2 launch turtlesim launch.py

tutorial based on turtlesim: https://docs.ros.org/en/humble/Tutorials/Beginner-CLI-Tools/Launching-Multiple-Nodes/Launching-Multiple-Nodes.html#tasks

A command line tool for recording data published on topics in your system. It accumulates the data passed on any number of topics and saves it in a database. You can then replay the data to reproduce the results of your tests and experiments. Recording topics is also a great way to share your work and allow others to recreate it. To view the individual messages, you would have to open up the database, in this case sqlite3, to examine it, which is beyond the scope of ROS 2.

Install it:

sudo apt-get install ros-humble-ros2bag \
                     ros-humble-rosbag2-storage-default-plugins

ros2 bag can only record data from topics that are published on.

• see a list of your system’s topics: ros2 topic list
• To record the data published to a topic: ros2 bag record <topic_name>
• see details about your recording: ros2 bag info <bag_file_name>
• replaying the bag file: ros2 bag play <bag_file_name>

tutorial based on turtlesim: https://docs.ros.org/en/humble/Tutorials/Beginner-CLI-Tools/Recording-And-Playing-Back-Data/Recording-And-Playing-Back-Data.html#tasks

A ROS workspace is a directory with a particular structure. Commonly there is a /src subdirectory. Inside that subdirectory is where the source code of ROS packages will be located. Typically the directory starts otherwise empty. colcon is an iteration on the ROS build tools catkin_make, catkin_make_isolated, catkin_tools and ament_tools. more: Dirk Thomas - A universal build tool

colcon does out of source builds. By default it will create the following directories as peers of the src directory:

• /build - where intermediate files are stored. For each package a subfolder will be created in which
• /install - where each package will be installed, by default each package will be installed into a separate subdirectory.
• /log - contains various logging information about each colcon invocation

In general, it is recommended to use an overlay when you plan to iterate on a small number of packages, rather than putting all of your packages into the same workspace.

Since build types such as ament_cmake do not support the concept of the devel space and require the package to be installed, colcon supports the option --symlink-install. This allows the installed files to be changed by changing the files in the source space for faster iteration.

colcon build --symlink-install

To run tests for the packages we just built, run the following: colcon test

When colcon has completed building successfully, the output will be in the install directory. Before you can use any of the installed executables or libraries, you will need to add them to your path and library paths: . install/setup.bash

• colcon_cd * allows you to quickly change the current working directory of your shell to the directory of a package., ex: colcon_cd some_ros_package*, docs

demo: https://docs.ros.org/en/humble/Tutorials/Beginner-Client-Libraries/Colcon-Tutorial.html#try-a-demo

A workspace is a directory containing ROS 2 packages. Before using ROS 2, it’s necessary to source your ROS 2 installation workspace in the terminal you plan to work in. This makes ROS 2’s packages available for you to use in that terminal.

You also have the option of sourcing an “overlay” – a secondary workspace where you can add new packages without interfering with the existing ROS 2 workspace that you’re extending, or “underlay”. Your underlay must contain the dependencies of all the packages in your overlay. Packages in your overlay will override packages in the underlay. It’s also possible to have several layers of underlays and overlays, with each successive overlay using the packages of its parent underlays.

practices:

• create a new directory for every new workspace. The name doesn’t matter, but it is helpful to have it indicate the purpose of the workspace.
• put any packages in your workspace into the src directory.

Before building the workspace, you need to resolve package dependencies. You may have all the dependencies already, but best practice is to check for dependencies every time you clone. You wouldn’t want a build to fail after a long wait because of missing dependencies.

Using overlays is recommended for working on a small number of packages, so you don’t have to put everything in the same workspace and rebuild a huge workspace on every iteration.

• colcon build - build your packages

demo: https://docs.ros.org/en/humble/Tutorials/Beginner-Client-Libraries/Creating-A-Workspace/Creating-A-Workspace.html#tasks

A package can be considered a container for your ROS 2 code. If you want to be able to install your code or share it with others, then you’ll need it organized in a package. With packages, you can release your ROS 2 work and allow others to build and use it easily.

Package creation in ROS 2 uses ament as its build system and colcon as its build tool. You can create a package using either CMake or Python, which are officially supported, though other build types do exist.

minimum required contents:

CMake

• package.xml - meta information about the package
• CMakeLists.txt - describes how to build the code within the package

Python

• package.xml - meta information about the package
• setup.py - instructions for how to install the package
• setup.cfg - required when a package has executables
• /<package_name> - directory with the same name as your package, used by ROS 2 tools to find your package, contains __init__.py

A single workspace can contain as many packages as you want, each in their own folder. You can also have packages of different build types in one workspace. Best practice is to have a /src folder within your workspace, and to create your packages in there. This keeps the top level of the workspace “clean”.

Putting packages in a workspace is especially valuable because you can build many packages at once by running colcon build in the workspace root. Otherwise, you would have to build each package individually.

ros2 pkg create --build-type ament_python <package_name>

tutorial based on turtlesim: https://docs.ros.org/en/humble/Tutorials/Beginner-Client-Libraries/Creating-Your-First-ROS2-Package.html#tasks

The same can be solved via rospy like this: rospy/Overview/Publishers and Subscribers

Nodes are executable processes that communicate over the ROS graph. The example used here is a simple “talker” and “listener” system; one node publishes data and the other subscribes to the topic so it can receive that data.

note:

• for this you should change metadata in CMakeLists.txt - Publisher, Subscriber
• add dependencies in package.xml - example

More about this at:

• http://wiki.ros.org/ROS/Tutorials/WritingPublisherSubscriber%28python%29
• https://github.com/ros2torial/ros2_basics
• https://youtu.be/Gg25GfA456o?t=2378

Publisher

In c++

you should include:

• #include "rclcpp/rclcpp.hpp" - allows you to use the most common pieces of the ROS 2 system
  • rclpp - provides the standard C++ API for interacting with ROS 2.
• #include "std_msgs/msg/string.hpp" - built-in message type you will use to publish data

    class MinimalPublisher : public rclcpp::Node  //creates the node class MinimalPublisher by inheriting from rclcpp::Node
    {
      public:
        MinimalPublisher()  //public constructor 
        : Node("minimal_publisher"), count_(0)  //names the node minimal_publisher and initializes count_ to 0
        {
          publisher_ = this->create_publisher<std_msgs::msg::String>("topic", 10);   //the publisher is initialized with the String message type, the topic name topic, and the required queue size 
                                                                                     // queue size limit number of messages in the event of a backup
          timer_ = this->create_wall_timer(
          500ms, std::bind(&MinimalPublisher::timer_callback, this));   //timer_callback function will be executed twice a second
        }

      private:
        void timer_callback()   //this is where the message data is set and the messages are actually published
        {
          auto message = std_msgs::msg::String();
          message.data = "Hello, world! " + std::to_string(count_++);
          RCLCPP_INFO(this->get_logger(), "Publishing: '%s'", message.data.c_str());   //this macro ensures every published message is printed to the console.
          publisher_->publish(message);
        }
        
        //declaration of the timer, publisher, and counter
        rclcpp::TimerBase::SharedPtr timer_;
        rclcpp::Publisher<std_msgs::msg::String>::SharedPtr publisher_;
        size_t count_;
    };

In Python...

In Python you shold include:

• import rclpy
• from rclpy.node import Node
• from std_msgs.msg import String

class MinimalPublisher(Node):   #inherits from (or is a subclass of) `Node`

    def __init__(self):
        super().__init__('minimal_publisher')   # calls the Node class’s constructor and gives it your node name -> this case `minimal_publisher`
        self.publisher_ = self.create_publisher(String, 'topic', 10)   # declares that the node publishes messages of type String (imported from the std_msgs.msg module), over a topic named "topic"; the “queue size” is 10
        ## Queue size is a required QoS (quality of service) setting that limits the amount of queued messages if a subscriber is not receiving them fast enough.
        
        
        timer_period = 0.5  # seconds
        self.timer = self.create_timer(timer_period, self.timer_callback)   #a callback to execute every 0.5 seconds
                                                                            #creates a message with the counter value appended, and publishes it to the console
        self.i = 0   #a counter used in the callback.

    def timer_callback(self):
        msg = String()
        msg.data = 'Hello World: %d' % self.i
        self.publisher_.publish(msg)
        self.get_logger().info('Publishing: "%s"' % msg.data)   #this publishes the data on the console 
        self.i += 1


def main(args=None):
    rclpy.init(args=args)

    minimal_publisher = MinimalPublisher()

    rclpy.spin(minimal_publisher)   # its callbacks are called

    # Destroy the node explicitly
    # (optional - otherwise it will be done automatically
    # when the garbage collector destroys the node object)
    minimal_publisher.destroy_node()
    rclpy.shutdown()

Subscriber

In c++

nearly identical to the publisher

class MinimalSubscriber : public rclcpp::Node
{
  public:
    MinimalSubscriber()
    : Node("minimal_subscriber")
    {
      subscription_ = this->create_subscription<std_msgs::msg::String>(   //There is no timer because the subscriber simply responds whenever data is published to the "topic" topic.
      "topic", 10, std::bind(&MinimalSubscriber::topic_callback, this, _1));   //the topic name and message type used by the publisher and subscriber must match 
    }

  private:
    void topic_callback(const std_msgs::msg::String & msg) const   // receives the string message data published over the topic
    {
      RCLCPP_INFO(this->get_logger(), "I heard: '%s'", msg.data.c_str());   //imply writes the message data to the console using the RCLCPP_INFO macro.
    }
    rclcpp::Subscription<std_msgs::msg::String>::SharedPtr subscription_;
};

In Python

class MinimalSubscriber(Node):

    def __init__(self):
        super().__init__('minimal_subscriber')
        self.subscription = self.create_subscription(
            String,
            'topic',
            self.listener_callback,
            10)
        self.subscription  # prevent unused variable warning

    def listener_callback(self, msg):
        self.get_logger().info('I heard: "%s"' % msg.data)


def main(args=None):
    rclpy.init(args=args)

    minimal_subscriber = MinimalSubscriber()

    rclpy.spin(minimal_subscriber)

    # Destroy the node explicitly
    # (optional - otherwise it will be done automatically
    # when the garbage collector destroys the node object)
    minimal_subscriber.destroy_node()
    rclpy.shutdown()

to do at the end:

• check if everything is installed: rosdep install -i --from-path src --rosdistro humble -y
• build the package: colcon build --packages-select cpp_pubsub

Original sources:

• c++ code available here, detailed description of the code available here
• python code available here, detailed description of the code available here