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A library for integrating depth images into Truncated Signed Distance Fields.

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Yak

GitHub Actions status GitHub issues open license - MIT support level: consortium / vendor

Yak is a library for integrating depth images into Truncated Signed Distance Fields (TSDFs). It is currently supported for Ubuntu 16.04 and Ubuntu 18.04. An example ROS node using Yak is provided in the yak_ros repository.

A ROS interface is provided at yak_ros, and a ROS2 interface is provided at yak_ros2;

Attribution

This library was originally a fork of personalrobotics/kinfu_ros, and the underlying TSDF algorithm is very similar to the implementation used there.

Technical Background

A TSDF is a probabilistic representation of a solid surface in 3D space. It is a useful tool for combining many noisy incomplete sensor readings into a single smooth and complete model.

To break down the name:

  • Distance Field: Each voxel in the volume contains a value that represents its metric distance from the closest point on the surface. Voxels very far from the surface have high-magnitude distance values, while those near the surface have values approaching zero.

  • Signed: Voxels outside the surface have positive distances, while voxels inside the surface have negative distances. This allows the representation of solid objects. The distance field represents a gradient that shifts from positive to negative as it crosses the surface.

  • Truncated: Voxels further than a specified distance from the isosurface have their values capped at +/- 1 because we are only interested in precisely representing the region of the volume close to solid objects.

The TSDF algorithm can be efficiently parallelized on a general-purpose graphics processor, which allows data from RGB-D cameras to be integrated into the volume in real time. Numerous observations of an object from different perspectives average out noise and errors due to specular highlights and interreflections, producing a smooth continuous surface. This is a key advantage over equivalent point-cloud-centric strategies, which require additional processing to distinguish between engineered features and erroneous artifacts in the scan data. The volume can be converted to a triangular mesh using the Marching Cubes algorithm for consumption by application-specific processes.

Example Output

The picture below shows a mode of an aluminum part that was reconstructed using the TSDF algorithm and meshed using the Marching Cubes algorithm.

An aluminum part reconstructed as a TSDF and meshed with the Marching Cubes algorithm.

Dependencies

CMake

Yak requires CMake 3.10.0 or newer in order to take advantage of improved support for CUDA. If you're using Ubuntu 18.04 or newer you should already have a suitable version. If you're using an older distribution (e.g. 16.04) you will need to install a compatible version of CMake yourself.

  1. Install pip (if it isn't already installed):
sudo apt install python-pip
  1. Use pip to install a newer version of CMake locally, which will not overwrite the system installation of CMake.
pip install --user cmake --upgrade
  1. (Optional, depending on the specifics of your environment) Prepend the directory where CMake was just installed to the PATH environment variable. You may also add this to .bashrc.
export PATH=:/home/YOUR_USERNAME/.local/bin:$PATH

CUDA

Yak requires an NVidia GPU and CUDA 9.0 or newer.

  1. CUDA depends on Nvidia third-party drivers and will not work with the default Nouveau drivers. Determine which version of the Nvidia driver is compatible with your computer's GPU by running ubuntu-drivers devices. Usually the driver version listed as "third-party free recommended" is suitable. You can install the recommended driver using sudo ubuntu-drivers autoinstall. Example output listed below:
== /sys/devices/pci0000:00/0000:00:02.0/0000:02:00.0 ==
modalias : pci:v000010DEd000017C8sv00001458sd000036CBbc03sc00i00
vendor   : NVIDIA Corporation
model    : GM200 [GeForce GTX 980 Ti]
driver   : nvidia-driver-418 - third-party free recommended
driver   : nvidia-driver-410 - third-party free
driver   : nvidia-driver-390 - distro non-free
driver   : xserver-xorg-video-nouveau - distro free builtin
  1. Consult the chart below (copied from here as of Februray 13 2021) to find which CUDA version is compatible with the drivers supported by your GPU. Yak is currently not compatible with CUDA <= 8.0.
CUDA Toolkit Linux x86_64 Driver Version
CUDA 11.2 >= 450.80.02
CUDA 11.1 (11.1.0) >= 450.80.02
CUDA 11.0 (11.0.3) >= 450.36.06
CUDA 10.2 (10.2.89) >= 440.33
CUDA 10.1 (10.1.105) >= 418.39
CUDA 10.0 (10.0.130) >= 410.48
CUDA 9.2 (9.2.88) >= 396.26
CUDA 9.1 (9.1.85) >= 390.46
CUDA 9.0 (9.0.76) >= 384.81
CUDA 8.0 (8.0.61 GA2) >= 375.26
CUDA 8.0 (8.0.44) >= 367.48
CUDA 7.5 (7.5.16) >= 352.31
CUDA 7.0 (7.0.28) >= 346.46
  1. Specific installation instructions vary depending on the combination of Ubuntu version, CUDA version, and Nvidia driver version. Please read the linked instructions carefully: they are very important, and CUDA may not work correctly if you skip a step!
  1. Follow the instructions in Post-installation Actions. It is not necessary to complete the steps listed under "POWER9 Setup" -- you probably do not have a POWER9-compatible system unless you work with supercomputers.

OpenMP

Yak requires OpenMP for parallelization of the marching cubes surface reconstruction process.

sudo apt install libomp-dev

OpenCV

Yak requires OpenCV 3.0 or newer. If you are using ROS then this dependency is already satisfied. Otherwise you will need to install it yourself:

sudo apt install libopencv-dev

Eigen

Yak requires Eigen 3. If you are using ROS then this dependency is already satisfied. Otherwise you will need to install it yourself:

sudo apt install libeigen3-dev

PCL

Yak requires PCL 1.8 or newer. If you are using ROS then this dependency is already satisfied. Otherwise you will need to install it yourself:

sudo apt install libpcl-dev

ros_industrial_cmake_boilerplate

Yak depends on the ros_industrial_cmake_boilerplate package to facilitate package setup and installation.

Installation

Build with ROS (recommended)

Installing ROS is beyond the scope of this readme. There are installation instructions here for ROS1 and here for ROS2.

Clone this package into the src directory of a ROS workspace. For ROS1 use catkin build to build the workspace. For ROS2 use colcon build to build the workspace.

Take a look at the yak_ros package for example implementations of ROS nodes using Yak.

Build Standalone (in development)

git clone https://github.com/ros-industrial/yak.git
cd yak
mkdir build
cd build
cmake ../yak
make
sudo make install

Examples

yak_ros and yak_ros2 provide instructions for building and running ROS demo applications.

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A library for integrating depth images into Truncated Signed Distance Fields.

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