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Universal grid map library for mobile robotic mapping

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Grid Map

Overview

This is a C++ library with ROS interface to manage two-dimensional grid maps with multiple data layers. It is designed for mobile robotic mapping to store data such as elevation, variance, color, friction coefficient, foothold quality, surface normal, traversability etc. It is used in the Robot-Centric Elevation Mapping package designed for rough terrain navigation.

Features:

  • Multi-layered: Developed for universal 2.5-dimensional grid mapping with support for any number of layers.
  • Efficient map re-positioning: Data storage is implemented as two-dimensional circular buffer. This allows for non-destructive shifting of the map's position (e.g. to follow the robot) without copying data in memory.
  • Based on Eigen: Grid map data is stored as Eigen data types. Users can apply available Eigen algorithms directly to the map data for versatile and efficient data manipulation.
  • Convenience functions: Several helper methods allow for convenient and memory safe cell data access. For example, iterator functions for rectangular, circular, polygonal regions and lines are implemented.
  • ROS interface: Grid maps can be directly converted to and from ROS message types such as PointCloud2, OccupancyGrid, GridCells, and our custom GridMap message. Conversion packages provide compatibility with costmap_2d, PCL, and OctoMap data types.
  • OpenCV interface: Grid maps can be seamlessly converted from and to OpenCV image types to make use of the tools provided by OpenCV.
  • Visualizations: The grid_map_rviz_plugin renders grid maps as 3d surface plots (height maps) in RViz. Additionally, the grid_map_visualization package helps to visualize grid maps as point clouds, occupancy grids, grid cells etc.

The grid map package has been tested with ROS Indigo, Jade (under Ubuntu 14.04) and Kinetic (under Ubuntu 16.04). This is research code, expect that it changes often and any fitness for a particular purpose is disclaimed.

The source code is released under a BSD 3-Clause license.

Author: PĂ©ter Fankhauser
Maintainer: PĂ©ter Fankhauser, [email protected]
With contributions by: Jeff Delmerico, Remo Diethelm, Perry Franklin, Dominic Jud, Ralph Kaestner, Philipp KrĂĽsi, Alex Millane, Daniel Stonier, Elena Stumm, Martin Wermelinger, Christos Zalidis
Affiliation: Autonomous Systems Lab, ETH Zurich

Grid map example in RViz

Publications

If you use this work in an academic context, please cite the following publication(s):

  • P. Fankhauser and M. Hutter, "A Universal Grid Map Library: Implementation and Use Case for Rough Terrain Navigation", in Robot Operating System (ROS) – The Complete Reference (Volume 1), A. Koubaa (Ed.), Springer, 2016. (PDF)

      @incollection{Fankhauser2016GridMapLibrary,
          author = {Fankhauser, P{\'{e}}ter and Hutter, Marco},
          booktitle = {Robot Operating System (ROS) – The Complete Reference (Volume 1)},
          title = {{A Universal Grid Map Library: Implementation and Use Case for Rough Terrain Navigation}},
          chapter = {5},
          editor = {Koubaa, Anis},
          publisher = {Springer},
          year = {2016},
          isbn = {978-3-319-26052-5},
          doi = {10.1007/978-3-319-26054-9{\_}5},
          url = {http://www.springer.com/de/book/9783319260525}
      }
    

Documentation

An introduction to the grid map library including a tutorial is given in this book chapter.

The C++ API is documented here:

Installation

Installation from Packages

To install all packages from the grid map library as Debian packages use

sudo apt-get install ros-kinetic-grid-map

Building from Source

Dependencies

The grid_map_core package depends only on the linear algebra library Eigen.

sudo apt-get install libeigen3-dev

The other packages depend additionally on the ROS standard installation (roscpp, tf, filters, sensor_msgs, nav_msgs, and cv_bridge). Other format specific conversion packages (e.g. grid_map_cv, grid_map_pcl etc.) depend on packages described below in Packages Overview.

Building

To build from source, clone the latest version from this repository into your catkin workspace and compile the package using

cd catkin_ws/src
git clone https://github.com/ethz-asl/grid_map.git
cd ../
catkin_make

To maximize performance, make sure to build in Release mode. You can specify the build type by setting

catkin_make -DCMAKE_BUILD_TYPE=Release

Packages Overview

This repository consists of following packages:

  • grid_map is the meta-package for the grid map library.
  • grid_map_core implements the algorithms of the grid map library. It provides the GridMap class and several helper classes such as the iterators. This package is implemented without ROS dependencies.
  • grid_map_ros is the main package for ROS dependent projects using the grid map library. It provides the interfaces to convert grid maps from and to several ROS message types.
  • grid_map_demos contains several nodes for demonstration purposes.
  • grid_map_filters builds on the ROS filters package to process grid maps as a sequence of filters.
  • grid_map_msgs holds the ROS message and service definitions around the [grid_map_msg/GridMap] message type.
  • grid_map_rviz_plugin is an RViz plugin to visualize grid maps as 3d surface plots (height maps).
  • grid_map_visualization contains a node written to convert GridMap messages to other ROS message types for example for visualization in RViz.

Additional conversion packages:

  • grid_map_costmap_2d provides conversions of grid maps from costmap_2d map types.
  • grid_map_cv provides conversions of grid maps from and to OpenCV image types.
  • grid_map_octomap provides conversions of grid maps from OctoMap (OctoMap) maps.
  • grid_map_pcl provides conversions of grid maps from Point Cloud Library (PCL) polygon meshes.

Unit Tests

Run the unit tests with

catkin_make run_tests_grid_map_core run_tests_grid_map_ros

or

catkin build grid_map --no-deps --verbose --catkin-make-args run_tests

if you are using catkin tools.

Usage

Demonstrations

The grid_map_demos package contains several demonstration nodes. Use this code to verify your installation of the grid map packages and to get you started with your own usage of the library.

  • simple_demo demonstrates a simple example for using the grid map library. This ROS node creates a grid map, adds data to it, and publishes it. To see the result in RViz, execute the command

      roslaunch grid_map_demos simple_demo.launch
    
  • tutorial_demo is an extended demonstration of the library's functionalities. Launch the tutorial_demo with

      roslaunch grid_map_demos tutorial_demo.launch
    
  • iterators_demo showcases the usage of the grid map iterators. Launch it with

      roslaunch grid_map_demos iterators_demo.launch
    
  • image_to_gridmap_demo demonstrates how to convert data from an image to a grid map. Start the demonstration with

      roslaunch grid_map_demos image_to_gridmap_demo.launch
    

    Image to grid map demo result

  • opencv_demo demonstrates map manipulations with help of OpenCV functions. Start the demonstration with

      roslaunch grid_map_demos opencv_demo.launch
    

    OpenCV demo result

  • resolution_change_demo shows how the resolution of a grid map can be changed with help of the OpenCV image scaling methods. The see the results, use

      roslaunch grid_map_demos resolution_change_demo.launch
    

Conventions & Definitions

Grid map layers

Grid map conventions

Iterators

The grid map library contains various iterators for convenience.

Grid map Submap Circle Line Polygon
Grid map iterator Submap iterator Circle iterator Line iterator Polygon iterator
Ellipse Spiral
Ellipse iterator Spiral iterator

Using the iterator in a for loop is common. For example, iterate over the entire grid map with the GridMapIterator with

for (grid_map::GridMapIterator iterator(map); !iterator.isPastEnd(); ++iterator) {
    cout << "The value at index " << (*iterator).transpose() << " is " << map.at("layer", *iterator) << endl;
}

The other grid map iterators follow the same form. You can find more examples on how to use the different iterators in the iterators_demo node.

Note: For maximum efficiency when using iterators, it is recommended to locally store direct access to the data layers of the grid map with grid_map::Matrix& data = map["layer"] outside the for loop:

grid_map::Matrix& data = map["layer"];
for (GridMapIterator iterator(map); !iterator.isPastEnd(); ++iterator) {
    const Index index(*iterator);
    cout << "The value at index " << index.transpose() << " is " << data(index(0), index(1)) << endl;
}

You can find a benchmarking of the performance of the iterators in the iterator_benchmark node of the grid_map_demos package which can be run with

rosrun grid_map_demos iterator_benchmark

Beware that while iterators are convenient, it is often the cleanest and most efficient to make use of the built-in Eigen methods. Here are some examples:

  • Setting a constant value to all cells of a layer:

      map["layer"].setConstant(3.0);
    
  • Adding two layers:

      map["sum"] = map["layer_1"] + map["layer_2"];
    
  • Scaling a layer:

      map["layer"] = 2.0 * map["layer"];
    
  • Max. values between two layers:

      map["max"] = map["layer_1"].cwiseMax(map["layer_2"]);
    
  • Compute the root mean squared error:

      map.add("error", (map.get("layer_1") - map.get("layer_2")).cwiseAbs());
      unsigned int nCells = map.getSize().prod();
      double rootMeanSquaredError = sqrt((map["error"].array().pow(2).sum()) / nCells);
    

Changing the Position of the Map

There are two different methods to change the position of the map:

  • setPosition(...): Changes the position of the map without changing data stored in the map. This changes the corresponce between the data and the map frame.
  • move(...): Relocates the grid map such that the corresponce between data and the map frame does not change. Data in the overlapping region before and after the position change remains stored. Data that falls outside of the map at its new position is discarded. Cells that cover previously unknown regions are emptied (set to nan). The data storage is implemented as two-dimensional circular buffer to minimize computational effort.
setPosition(...) move(...)
Grid map iterator Submap iterator

Packages

grid_map_rviz_plugin

This RViz plugin visualizes a grid map layer as 3d surface plot (height map). A separate layer can be chosen as layer for the color information.

Grid map visualization in RViz

grid_map_visualization

This node subscribes to a topic of type grid_map_msgs/GridMap and publishes messages that can be visualized in RViz. The published topics of the visualizer can be fully configure with a YAML parameter file. Any number of visualizations with different parameters can be added. An example is here for the configuration file of the tutorial_demo.

Point cloud Vectors Occupancy grid Grid cells
Point cloud Vectors Occupancy grid Grid cells

Parameters

  • grid_map_topic (string, default: "/grid_map")

    The name of the grid map topic to be visualized. See below for the description of the visualizers.

Subscribed Topics

Published Topics

The published topics are configured with the YAML parameter file. Possible topics are:

  • point_cloud (sensor_msgs/PointCloud2)

    Shows the grid map as a point cloud. Select which layer to transform as points with the layer parameter.

      name: elevation
      type: point_cloud
      params:
       layer: elevation
       flat: false # optional
    
  • flat_point_cloud (sensor_msgs/PointCloud2)

    Shows the grid map as a "flat" point cloud, i.e. with all points at the same height z. This is convenient to visualize 2d maps or images (or even video streams) in RViz with help of its Color Transformer. The parameter height determines the desired z-position of the flat point cloud.

      name: flat_grid
      type: flat_point_cloud
      params:
       height: 0.0
    

    Note: In order to omit points in the flat point cloud from empty/invalid cells, specify the layers which should be checked for validity with setBasicLayers(...).

  • vectors (visualization_msgs/Marker)

    Visualizes vector data of the grid map as visual markers. Specify the layers which hold the x-, y-, and z-components of the vectors with the layer_prefix parameter. The parameter position_layer defines the layer to be used as start point of the vectors.

      name: surface_normals
      type: vectors
      params:
       layer_prefix: normal_
       position_layer: elevation
       scale: 0.06
       line_width: 0.005
       color: 15600153 # red
    
  • occupancy_grid (nav_msgs/OccupancyGrid)

    Visualizes a layer of the grid map as occupancy grid. Specify the layer to be visualized with the layer parameter, and the upper and lower bound with data_min and data_max.

      name: traversability_grid
      type: occupancy_grid
      params:
       layer: traversability
       data_min: -0.15
       data_max: 0.15
    
  • grid_cells (nav_msgs/GridCells)

    Visualizes a layer of the grid map as grid cells. Specify the layer to be visualized with the layer parameter, and the upper and lower bounds with lower_threshold and upper_threshold.

      name: elevation_cells
      type: grid_cells
      params:
       layer: elevation
       lower_threshold: -0.08 # optional, default: -inf
       upper_threshold: 0.08 # optional, default: inf
    
  • region (visualization_msgs/Marker)

    Shows the boundary of the grid map.

      name: map_region
      type: map_region
      params:
       color: 3289650
       line_width: 0.003
    

Note: Color values are in RGB form as concatenated integers (for each channel value 0-255). The values can be generated like this as an example for the color green (red: 0, green: 255, blue: 0).

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Please report bugs and request features using the Issue Tracker.

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