Additional Simulation Worlds

In addtion to the default ridgeback_world.launch file, ridgeback_gazebo also contains spawn_ridgeback.launch, which is intended to be included in any custom world to add a Ridgeback simulation to it.

To add a Ridgeback to any of your own worlds, simply include the spawn_ridgeback.launch file in your own world’s launch:

<include file="$(find ridgeback_gazebo)/launch/spawn_ridgeback.launch">
  <!-- Optionally configure the spawn position -->
  <arg name="x" value="$(arg x)"/>
  <arg name="y" value="$(arg y)"/>
  <arg name="z" value="$(arg z)"/>
  <arg name="yaw" value="$(arg yaw)"/>
</include>

Clearpath also provides an additional suite of simulation environments that can be downloaded separately and used with Ridgeback, as described below.

Clearpath Gazebo Worlds

The Clearpath Gazebo Worlds collection contains 4 different simulation worlds, representative of different environments our robots are designed to operate in:

• Inspection World: a hilly outdoor world with water and a cave

• Agriculture World: a flat outdoor world with a barn, fences, and solar farm

• Office World: a flat indoor world with enclosed rooms and furniture

• Construction World: office world, under construction with small piles of debris and partial walls

Ridgeback is supported in Office and Construction Worlds.

Installation

To download the Clearpath Gazebo Worlds, clone the repository from github into the same workspace as your Ridgeback:

cd ~/catkin_ws/src
git clone https://github.com/clearpathrobotics/cpr_gazebo.git

Before you can build the package, make sure to install dependencies. Because Clearpath Gazebo Worlds depends on all of our robots’ simulation packages, and some of these are currently only available as source code, installing dependencies with rosdep install --from-paths [...] will likely fail.

All four simulation environments need the gazebo_ros package. The Inspection World also needs the uuv_gazebo_worlds package, which can be installed by running

sudo apt-get install ros-$ROS_DISTRO-uuv-gazebo-worlds

Once the dependencies are installed, you can build the package:

cd ~/catkin_ws
catkin_make
source devel/setup.bash

Running the Office Simulation

Office World is a small indoor environment representing a commercial office space. It features several large, open areas with furniture, as well as a narrow hallway with smaller offices and meeting rooms. It is intended to simulate missions in commercial spaces, such as facilitating deliveries, security monitoring, and inspecting equipment.

To launch Office World with a Ridgeback, run the following command:

roslaunch cpr_office_gazebo office_world.launch platform:=ridgeback

To customize Ridgeback’s payload, for example to add additional sensors, see Customizing Ridgeback’s Payload.

Once the simulation is running you can use rviz and other tools as described in Simulating Ridgeback and Navigating with Ridgeback to control and monitor the robot. For example, below we can see the gmapping_demo from ridgeback_navigation being used to build a map of the office world:

You can see the complete layout of the office world below:

Running the Construction Simulation

Construction World is the same basic layout as Office World, representing the same office space under construction/rennovation. It is an indoor environment with small hills of debris/rubble, partial walls, and piles of construction supplies. It is designed to simulate missions in any sort of construction site.

To launch Construction World with a Ridgeback, run the following command:

roslaunch cpr_office_gazebo office_construction_world.launch platform:=ridgeback

To customize Ridgeback’s payload, for example to add additional sensors, see Customizing Ridgeback’s Payload.

Once the simulation is running you can use rviz and other tools as described in Simulating Ridgeback and Navigating with Ridgeback to control and monitor the robot.

You can see the complete layout of the office below:

Customizing Ridgeback’s Payload

To customize Ridgeback’s payload you must use the environment variables described in Configuration & Environment Variables. For example, to equip Ridgeback with a Sick LMS-1xx lidar, as pictured in several of the images above, run

export RIDGEBACK_LASER=1

before launching the simulation world.

You can also add additional sensors by creating a customized URDF and setting the RIDGEBACK_URDF_EXTRAS environment variable to point to it.

For example, let’s suppose you want to equip Ridgeback with an Intel RealSense D435 camera. First, install the realsense2_camera and realsense2_description packages, along with the gazebo plugins:

sudo apt-get install ros-$ROS_DISTRO-realsense2-camera ros-$ROS_DISTRO-realsense2-description ros-$ROS_DISTRO-gazebo-plugins

Then create your customized URDF file, for example $HOME/Desktop/realsense.urdf.xacro. Put the following in it:

<?xml version="1.0"?>
<robot xmlns:xacro="http://ros.org/wiki/xacro">

  <link name="front_realsense" />

  <!--
    The gazebo plugin aligns the depth data with the Z axis, with X=left and Y=up
    ROS expects the depth data along the X axis, with Y=left and Z=up
    This link only exists to give the gazebo plugin the correctly-oriented frame
  -->
  <link name="front_realsense_gazebo" />
  <joint name="front_realsense_gazebo_joint" type="fixed">
    <parent link="front_realsense"/>
    <child link="front_realsense_gazebo"/>
    <origin xyz="0.0 0 0" rpy="-1.5707963267948966 0 -1.5707963267948966"/>
  </joint>

  <gazebo reference="front_realsense">
    <turnGravityOff>true</turnGravityOff>
    <sensor type="depth" name="front_realsense_depth">
      <update_rate>30</update_rate>
      <camera>
        <!-- 75x65 degree FOV for the depth sensor -->
        <horizontal_fov>1.5184351666666667</horizontal_fov>
        <vertical_fov>1.0122901111111111</vertical_fov>

        <image>
          <width>640</width>
          <height>480</height>
          <format>RGB8</format>
        </image>
        <clip>
          <!-- give the color sensor a maximum range of 50m so that the simulation renders nicely -->
          <near>0.01</near>
          <far>50.0</far>
        </clip>
      </camera>
      <plugin name="kinect_controller" filename="libgazebo_ros_openni_kinect.so">
        <baseline>0.2</baseline>
        <alwaysOn>true</alwaysOn>
        <updateRate>30</updateRate>
        <cameraName>realsense</cameraName>
        <imageTopicName>color/image_raw</imageTopicName>
        <cameraInfoTopicName>color/camera_info</cameraInfoTopicName>
        <depthImageTopicName>depth/image_rect_raw</depthImageTopicName>
        <depthImageInfoTopicName>depth/camera_info</depthImageInfoTopicName>
        <pointCloudTopicName>depth/color/points</pointCloudTopicName>
        <frameName>front_realsense_gazebo</frameName>
        <pointCloudCutoff>0.105</pointCloudCutoff>
        <pointCloudCutoffMax>8.0</pointCloudCutoffMax>
        <distortionK1>0.00000001</distortionK1>
        <distortionK2>0.00000001</distortionK2>
        <distortionK3>0.00000001</distortionK3>
        <distortionT1>0.00000001</distortionT1>
        <distortionT2>0.00000001</distortionT2>
        <CxPrime>0</CxPrime>
        <Cx>0</Cx>
        <Cy>0</Cy>
        <focalLength>0</focalLength>
        <hackBaseline>0</hackBaseline>
      </plugin>
    </sensor>
  </gazebo>

  <link name="front_realsense_lens">
    <visual>
      <origin xyz="0.02 0 0" rpy="${pi/2} 0 ${pi/2}" />
      <geometry>
        <mesh filename="package://realsense2_description/meshes/d435.dae" />
      </geometry>
      <material name="white" />
    </visual>
  </link>

  <joint type="fixed" name="front_realsense_lens_joint">
    <!-- Offset the camera 45cm forwards and 1cm up -->
    <origin xyz="0.45 0 0.01" rpy="0 0 0" />
    <parent link="mid_mount" />
    <child link="front_realsense_lens" />
  </joint>
  <joint type="fixed" name="front_realsense_joint">
    <origin xyz="0.025 0 0" rpy="0 0 0" />
    <parent link="front_realsense_lens" />
    <child link="front_realsense" />
  </joint>
</robot>

This file defines the additional links for adding a RealSense camera to the robot, as well as configuring the openni_kinect plugin for Gazebo to simulate data from a depth camera. The camera itself will be connected to the Ridgeback’s front_mount link, offset 5cm towards the front of the robot.

Now, set the RIDGEBACK_URDF_EXTRAS environment variable and try viewing the Ridgeback model:

export RIDGEBACK_URDF_EXTRAS=$HOME/Desktop/realsense.urdf.xacro
roslaunch ridgeback_viz view_model.launch

You should see the Ridgeback model in rviz, with the RealSense camera mounted to it:

To launch the customized Ridgeback in any of the new simulation environments, similarly run:

export RIDGEBACK_URDF_EXTRAS=$HOME/Desktop/realsense.urdf.xacro
roslaunch cpr_office_gazebo office_world.launch platform:=ridgeback

You should see Ridgeback spawn in the office world with the RealSense camera:

You can view the sensor data from the RealSense camera by running

roslaunch ridgeback_viz view_robot.launch

and adding the camera & pointcloud from the /realsense/color/image_raw and /realsense/depth/color/points topics: