fdcl-gwu / aruco-markers

Working examples/tutorial for detection and pose estimation of ArUco markers with C++, including instructions to build and install OpenCV from source.
BSD 3-Clause "New" or "Revised" License
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ar aruco aruco-library aruco-markers augmented-reality c-plus-plus cpp examples opencv opencv-install opencv3 opencv4 tutorial

ArUco Markers

:bangbang: IMPORTANT: This assumes you are using OpenCV4. If you need to use OpenCV3, please checkout the cv3 branch before installing dependencies. As there are a few breaking changes in OpenCV libraries, some parts of the OpenCV4 codes are not compatible with OpenCV3.

This repository includes codes that can be used to work with the augmented reality library, ArUco. A few programs in the repository, including the codes to create the markers and to calibrate the cameras, are copies of the examples included with the OpenCV libraries with minor changes. Those are added here so that everything is in one place.

Contents

  1. Installing OpenCV
    1. Installing v4.5.3 (recommended)
    2. Installing the Latest
    3. Docker Build
  2. Generating Markers
  3. Detecting the Markers
  4. Camera Calibration
  5. Pose Estimation
  6. Draw a Cube

Installing OpenCV

You can install the standalone ArUco library by downloading the source files which can be found in the above website and building and installing them. But it is highly recommended to install ArUco library packed in OpenCV library. The instruction below are for installing OpenCV with ArUco library. These have been verified to work with Ubuntu 20.04.

If you are on a different OS, and/or prefer Docker, a dockerfile is included with this. Please skip to the Docker Build section.

You can install OpenCV using the master branch of their repository, OR using the submodules added to this repository. Building and installing OpenCV with the provided submodules guarantees that the other codes on this repository work without issues. So it is recommended to install from the submodules.

Installing v4.5.3 (recommended)

sudo apt install build-essential
sudo apt install cmake git libgtk2.0-dev pkg-config

# Image support
sudo apt install -y libtbb2 libtbb-dev libjpeg-dev libpng-dev libtiff-dev

# Video support
sudo apt install -y libavcodec-dev libavformat-dev libswscale-dev

cd <any directory you want to use>
git clone https://github.com/fdcl-gwu/aruco-markers.git
cd aruco-markers
git submodule update --init
cd libraries/opencv
mkdir build && cd build
cmake -DCMAKE_BUILD_TYPE=Release -DCMAKE_INSTALL_PREFIX=/usr/local -DOPENCV_EXTRA_MODULES_PATH=../../opencv_contrib/modules ..
make -j4  # if you have more/less cores on your computer, substitute 4 with the number of cores
          # use command "nproc" to find the number of cores
sudo make install

Installing the Latest

sudo apt install build-essential
sudo apt install cmake git libgtk2.0-dev pkg-config

# Image support
sudo apt install -y libtbb2 libtbb-dev libjpeg-dev libpng-dev libtiff-dev

# Video support
sudo apt install -y libavcodec-dev libavformat-dev libswscale-dev

git clone https://github.com/opencv/opencv.git
git clone https://github.com/opencv/opencv_contrib.git

# If you need a specific version, you should checkout that version on 
# both the repositories before executing the below commands.

mkdir build && cd build
cmake -DCMAKE_BUILD_TYPE=Release -DCMAKE_INSTALL_PREFIX=/usr/local -DOPENCV_EXTRA_MODULES_PATH=../../opencv_contrib/modules ..
make -j4  # if you have more/less cores on your computer, substitute 4 with the number of cores
          # use command "nproc" to find the number of cores
sudo make install

Docker Build

Following instructions are for a Linux host. Though Docker should work for any OS, the GUI setup used here is only has been tested on a Linux host. If you are on Windows or Mac, you will need to install an X Server, for example Xming, to get the GUI to work.

You have two options here:

  1. Pulling Docker image from hub - easy and fast
  2. Create the Docker image from scratch - slow, but you get more transparency

Pulling Docker Image

  1. Install Docker
  2. Open a terminal and run

    # Pull the Docker image
    docker pull kanishgama/aruco-markers:opencv-4.5.3
    
    # Enable xhost - required for GUI
    xhost +
    
    # Replace "-it aruco-markers bash" with "-it kanishgama/aruco-markers:opencv-4.5.3", then start a container
    bash docker_start.sh

Create Docker Image Manually

  1. Install Docker

  2. Open a terminal and run:

    cd <any directory you want to use>
    git clone https://github.com/fdcl-gwu/aruco-markers.git
    cd aruco-markers
    
    # Enable xhost - required for GUI
    xhost +
    
    # Build the docker image
    bash docker_build.sh
    
    # Run a container 
    bash docker_start.sh
    
    # After starting the container, you should be inside the docker.
    # Run the OpenCV install script (only required to do the first time).
    # This builds opencv, and install it. The process can take a considerable
    # amount of time depending on your computer.
    cd aruco-markers
    bash docker_opencv_setup.sh
    
    # After running the OpenCV install script, for any subsequent run, you only
    # have to run the docker run bash docker_start.sh script.
  3. Follow below code compiling instructions.

Generating Markers

To detect the markers using a camera, first you need to print the markers. The ArUco library comes with few functions to generate the markers, and they are copied to this repository for the ease of finding them.

cd create_markers
mkdir build && cd build
cmake ../
make

# Create a single marker.
# For details about the parameters, run just ./generate_marker
./generate_marker --b=1 -d=16 --id=108 --ms=400 --si marker.jpg

# Create a marker board.
# For details about the parameters, run just ./generate_board
./generate_board --bb=1 -h=2 -w=4 -l=200 -s=100 -d=16 --si board.jpg

The generated marker should look like this:

The generated board should look like this:

Detecting the Markers

First, print the generated markers. Connect a camera to the computer and run below commands:

cd detect_marker
mkdir build && cd build
cmake ../
make

# Running the following will open the your system camera and detect all the markers from the defined library.
./detect_markers

# If you just need to test, and you do not have a printed marker handy, try the test video in this repo with the below command.
./detect_markers -v=../../test_data/test_video.mp4 

All the detected markers would be drawn on the image.

 

Camera Calibration

To accurately detect markers or to get accurate pose data, a camera calibration needs to be performed.

Run below commands to perform the camera calibration:

cd camera_calibration
mkdir build && cd build
cmake ../
make

# Below command is accurate only if you used the same parameters when you generated the markers.
# If you changed any of them, change below arguments accordingly.
./camera_calibration -d=16 -dp=../detector_params.yml -h=2 -w=4 -l=<side length of a single marker (in meters)> -s=<separation between two consecutive markers in the grid (in meters)> ../../calibration_params.yml

# If you want to calibrate with an already saved video, use `-v` flag. For example, for the test video:
./camera_calibration -v=../../test_data/test_video.mp4 -d=16 -dp=../detector_params.yml -h=2 -w=4 -l=0.3 -s=0.15 ../../calibration_params.yml

Then point the camera at the marker at different orientations and at different angles, and save those images by pressing key C. These instructions should appear on the screen. Around 30 images should be good enough.

Pose Estimation

To estimate the translation and the rotation of the ArUco marker, run below code:

cd pose_estimation

mkdir build && cd build
cmake ../
make

./pose_estimation -l=<side length of a single marker (in meters)>

# For example, for the test video:
./pose_estimation -l=0.3 -v=../../test_data/test_video.mp4

Below image shows the output of this code. The distances shown in the left top corner are in meters with axes as same as those defined in OpenCV model, i.e., x-axis increases from left to right of the image, y-axis increases from top to bottom of the image, and the z-axis points outwards the camera, with the origin on the top left corner of the image. The axes drawn on the markers represent the orientation of the marker with the Red-Green-Blue axes order.

 

Draw a Cube

To estimate pose and draw a cube over the ArUco marker, run below code:

cd draw_cube

mkdir build && cd build
cmake ../
make

./draw_cube -l=<side length of a single marker (in meters)>

For example, for the test video:
./draw_cube -l=0.3 -v=../../test_data/test_video.mp4

Below GIF shows the output of this code.