October 18, 2019

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OpenDroneMap/ODM

OpenDroneMap/ODM

A command line toolkit to generate maps, point clouds, 3D models and DEMs from drone, balloon or kite images.

repo name OpenDroneMap/ODM
repo link https://github.com/OpenDroneMap/ODM
homepage https://www.opendronemap.org
language Python
size (curr.) 1102616 kB
stars (curr.) 2601
created 2014-09-25
license GNU General Public License v3.0

For documentation, see https://docs.opendronemap.org and Quickstart below

What is it?

ODM is an open source command line toolkit for processing aerial drone imagery. Typical drones use simple point-and-shoot cameras, so the images from drones, while from a different perspective, are similar to any pictures taken from point-and-shoot cameras, i.e. non-metric imagery. OpenDroneMap turns those simple images into three dimensional geographic data that can be used in combination with other geographic datasets.

If you want a graphical user interface for it, check out WebODM

In a word, ODM is a toolchain for processing raw civilian UAS imagery to other useful products. What kind of products?

  1. Point Clouds
  2. Digital Surface Models
  3. Textured Digital Surface Models
  4. Orthorectified Imagery
  5. Classified Point Clouds (coming soon)
  6. Digital Elevation Models
  7. etc.

ODM now includes state-of-the-art 3D reconstruction work by Michael Waechter, Nils Moehrle, and Michael Goesele. See their publication at http://www.gcc.tu-darmstadt.de/media/gcc/papers/Waechter-2014-LTB.pdf.

Quickstart

Docker (All platforms)

The easiest way to run ODM is through Docker. If you don’t have it installed, see the Docker Ubuntu installation tutorial and follow the instructions through “Create a Docker group”. The Docker image workflow has equivalent procedures for Mac OS X and Windows found at docs.docker.com. Then run the following command which will build a pre-built image and run on images found in $(pwd)/images (you can change this if you need to, see the wiki for more detailed instructions.

docker run -it --rm \
    -v "$(pwd)/images:/code/images" \
    -v "$(pwd)/odm_orthophoto:/code/odm_orthophoto" \
    -v "$(pwd)/odm_texturing:/code/odm_texturing" \
    opendronemap/odm

Native Install (Ubuntu 16.04)

** Please note that we need help getting ODM updated to work for 16.10+. Look at #659.

Download the latest release here

  1. Extract and enter the OpenDroneMap directory
  2. Run bash configure.sh install
  3. Edit the settings.yaml file in your favorite text editor. Set the project-path value to an empty directory (you will place sub-directories containing individual projects inside). You can add many options to this file, see here
  4. Download a sample dataset from here (about 550MB) and extract it as a subdirectory in your project directory.
  5. Run ./run.sh odm_data_aukerman
  6. Enter dataset directory to view results:
    • orthophoto: odm_orthophoto/odm_orthophoto.tif
    • textured mesh model: odm_texturing/odm_textured_model_geo.obj
    • point cloud (georeferenced): odm_georeferencing/odm_georeferenced_model.ply

See below for more detailed installation instructions.

Diving Deeper

Installation

Extract and enter the downloaded OpenDroneMap directory and compile all of the code by executing a single configuration script (requires root privileges):

bash configure.sh install

When updating to a newer version of ODM, it is recommended that you run

bash configure.sh reinstall

to ensure all the dependent packages and modules get updated.

For Ubuntu 15.10 users, this will help you get running:

sudo apt-get install python-xmltodict
sudo ln -s /usr/lib/x86_64-linux-gnu/libproj.so.9 /usr/lib/libproj.so

Environment Variables

There are some environmental variables that need to be set. Open the ~/.bashrc file on your machine and add the following 3 lines at the end. The file can be opened with gedit ~/.bashrc if you are using an Ubuntu desktop environment. Be sure to replace the “/your/path/” with the correct path to the location where you extracted OpenDroneMap:

export PYTHONPATH=$PYTHONPATH:/your/path/OpenDroneMap/SuperBuild/install/lib/python2.7/dist-packages
export PYTHONPATH=$PYTHONPATH:/your/path/OpenDroneMap/SuperBuild/src/opensfm
export LD_LIBRARY_PATH=$LD_LIBRARY_PATH:/your/path/OpenDroneMap/SuperBuild/install/lib

Note that using run.sh sets these temporarily in the shell.

Run OpenDroneMap

First you need a set of images, taken from a drone or otherwise. Example data can be obtained from https://github.com/OpenDroneMap/odm_data

Next, you need to edit the settings.yaml file. The only setting you must edit is the project-path key. Set this to an empty directory within projects will be saved. There are many options for tuning your project. See the wiki or run python run.py -h

Then run:

python run.py -i /path/to/images project-name

The images will be copied over to the project path so you only need to specify the -i /path/ once. You can also override any variable from settings.yaml here using the command line arguments. If you want to rerun the whole thing, run

python run.py --rerun-all project-name

or

python run.py --rerun-from odm_meshing project-name

The options for rerunning are: ‘resize’, ‘opensfm’, ‘slam’, ‘mve’, ‘odm_meshing’, ‘mvs_texturing’, ‘odm_georeferencing’, ‘odm_orthophoto’

View Results

When the process finishes, the results will be organized as follows:

|-- images/
    |-- img-1234.jpg
    |-- ...
|-- images_resize/
    |-- img-1234.jpg
    |-- ...
|-- opensfm/
    |-- see mapillary/opensfm repository for more info
    |-- depthmaps/
        |-- merged.ply                  # Dense Point cloud (not georeferenced)
|-- odm_meshing/
    |-- odm_mesh.ply                    # A 3D mesh
    |-- odm_meshing_log.txt             # Output of the meshing task. May point out errors.
|-- odm_texturing/
    |-- odm_textured_model.obj          # Textured mesh
    |-- odm_textured_model_geo.obj      # Georeferenced textured mesh
    |-- texture_N.jpg                   # Associated textured images used by the model
|-- odm_georeferencing/
    |-- odm_georeferenced_model.ply     # A georeferenced dense point cloud
    |-- odm_georeferenced_model.laz     # LAZ format point cloud
    |-- odm_georeferenced_model.csv     # XYZ format point cloud
    |-- odm_georeferencing_log.txt      # Georeferencing log
    |-- odm_georeferencing_transform.txt# Transform used for georeferencing
    |-- odm_georeferencing_utm_log.txt  # Log for the extract_utm portion
|-- odm_orthophoto/
    |-- odm_orthophoto.png              # Orthophoto image (no coordinates)
    |-- odm_orthophoto.tif              # Orthophoto GeoTiff
    |-- odm_orthophoto_log.txt          # Log file
    |-- gdal_translate_log.txt          # Log for georeferencing the png file

Any file ending in .obj or .ply can be opened and viewed in MeshLab or similar software. That includes opensfm/depthmaps/merged.ply, odm_meshing/odm_mesh.ply, odm_texturing/odm_textured_model[_geo].obj, or odm_georeferencing/odm_georeferenced_model.ply. Below is an example textured mesh:

You can also view the orthophoto GeoTIFF in QGIS or other mapping software:

Build and Run Using Docker

(Instructions below apply to Ubuntu 14.04, but the Docker image workflow has equivalent procedures for Mac OS X and Windows. See docs.docker.com)

OpenDroneMap is Dockerized, meaning you can use containerization to build and run it without tampering with the configuration of libraries and packages already installed on your machine. Docker software is free to install and use in this context. If you don’t have it installed, see the Docker Ubuntu installation tutorial and follow the instructions through “Create a Docker group”. Once Docker is installed, the fastest way to use OpenDroneMap is to run a pre-built image by typing:

docker run -it --rm \
    -v "$(pwd)/images:/code/images" \
    -v "$(pwd)/odm_orthophoto:/code/odm_orthophoto" \
    -v "$(pwd)/odm_texturing:/code/odm_texturing" \
    opendronemap/odm

If you want to build your own Docker image from sources, type:

docker build -t my_odm_image --no-cache .
docker run -it --rm \
    -v "$(pwd)/images:/code/images" \
    -v "$(pwd)/odm_orthophoto:/code/odm_orthophoto" \
    -v "$(pwd)/odm_texturing:/code/odm_texturing" \
    my_odm_image

Using this method, the containerized ODM will process the images in the OpenDroneMap/images directory and output results to the OpenDroneMap/odm_orthophoto and OpenDroneMap/odm_texturing directories as described in the Viewing Results section. If you want to view other results outside the Docker image simply add which directories you’re interested in to the run command in the same pattern established above. For example, if you’re interested in the dense cloud results generated by OpenSfM and in the orthophoto, simply use the following docker run command after building the image:

docker run -it --rm \
    -v "$(pwd)/images:/code/images" \
    -v "$(pwd)/odm_georeferencing:/code/odm_georeferencing" \
    -v "$(pwd)/odm_orthophoto:/code/odm_orthophoto" \
    my_odm_image

If you want to get all intermediate outputs, run the following command:

docker run -it --rm \
    -v "$(pwd)/images:/code/images" \
    -v "$(pwd)/odm_georeferencing:/code/odm_georeferencing" \
    -v "$(pwd)/odm_meshing:/code/odm_meshing" \
    -v "$(pwd)/odm_orthophoto:/code/odm_orthophoto" \
    -v "$(pwd)/odm_texturing:/code/odm_texturing" \
    -v "$(pwd)/opensfm:/code/opensfm" \
    -v "$(pwd)/mve:/code/mve" \
    opendronemap/odm

To pass in custom parameters to the run.py script, simply pass it as arguments to the docker run command. For example:

docker run -it --rm \
    -v "$(pwd)/images:/code/images" \
    -v "$(pwd)/odm_orthophoto:/code/odm_orthophoto" \
    -v "$(pwd)/odm_texturing:/code/odm_texturing" \
    opendronemap/odm --resize-to 1800

If you want to pass in custom parameters using the settings.yaml file, you can pass it as a -v volume binding:

docker run -it --rm \
    -v "$(pwd)/images:/code/images" \
    -v "$(pwd)/odm_orthophoto:/code/odm_orthophoto" \
    -v "$(pwd)/odm_texturing:/code/odm_texturing" \
    -v "$(pwd)/settings.yaml:/code/settings.yaml" \
    opendronemap/odm

When building your own Docker image, if image size is of importance to you, you should use the --squash flag, like so:

docker build --squash -t my_odm_image .

This will clean up intermediate steps in the Docker build process, resulting in a significantly smaller image (about half the size).

Experimental flags need to be enabled in Docker to use the --squash flag. To enable this, insert the following into the file /etc/docker/daemon.json:

{
    "experimental": true
}

After this, you must restart docker by typing sudo service docker restart into your Linux terminal.

User Interface

A web interface and API to OpenDroneMap is currently under active development in the WebODM repository.

Documentation:

For documentation, see http://docs.opendronemap.org/ and https://github.com/OpenDroneMap/ODM/wiki. Check those places first if you are having problems. There’s also help at community forum, and if you still need help and think you’ve found a bug or need an enhancement, look through the issue queue or create one.

Developers

Help improve our software!

For Linux users, the easiest way to modify the software is to make sure docker is installed, clone the repository and then run from a shell:

$ DATA=/path/to/datasets ./start-dev-env.sh

Where /path/to/datasets is a directory where you can place test datasets (it can also point to an empty directory if you don’t have test datasets).

You can now make changes to the ODM source. When you are ready to test the changes you can simply invoke:

(odmdev) [user:/code] master+* ± ./run.sh --project-path /datasets mydataset

If you have questions, join the developer’s chat at https://community.opendronemap.org/c/developers-chat/21

  1. Try to keep commits clean and simple
  2. Submit a pull request with detailed changes and test results
  3. Have fun!
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