Popularity

5.4

Growing

Activity

5.2

Stars 840

Watchers 46

Forks 198

Last Commit about 2 months ago

Code Quality Rank: L1

Programming language: C++

License: BSD 2-clause "Simplified" License

Tags: Robotics

Latest version: v0.7.0

Robotics Library (RL) alternatives and similar libraries

Based on the "Robotics" category.
Alternatively, view Robotics Library (RL) alternatives based on common mentions on social networks and blogs.

PCL

9.4 9.3 L1 Robotics Library (RL) VS PCL

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7.7 2.6 Robotics Library (RL) VS ROS

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moveit

7.2 8.6 Robotics Library (RL) VS moveit

:robot: The MoveIt motion planning framework
MRPT

7.1 9.6 L1 Robotics Library (RL) VS MRPT

:zap: The Mobile Robot Programming Toolkit (MRPT)
FCL

6.3 2.2 L1 Robotics Library (RL) VS FCL

Flexible Collision Library
DART

5.7 9.3 L1 Robotics Library (RL) VS DART

DART: Dynamic Animation and Robotics Toolkit
AIKIDO

3.6 2.6 Robotics Library (RL) VS AIKIDO

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RobWork

- Robotics Library (RL) VS RobWork

A collection of C++ libraries for simulation and control of robot systems.
MOOS-IvP

- Robotics Library (RL) VS MOOS-IvP

A set of open source C++ modules for providing autonomy on robotic platforms, in particular autonomous marine vehicles.

* Code Quality Rankings and insights are calculated and provided by Lumnify.
They vary from L1 to L5 with "L5" being the highest.

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README

Robotics Library

The Robotics Library (RL) is a self-contained C++ library for rigid body kinematics and dynamics, motion planning, and control. It covers spatial vector algebra, multibody systems, hardware abstraction, path planning, collision detection, and visualization. It is being used in research projects and in education, available under a BSD license, and free for use in commercial applications. RL runs on many different systems, including Linux, macOS, and Windows. It uses CMake as a build system and can be compiled with Clang, GCC, and Visual Studio.

Getting Started

We offer precompiled Ubuntu packages on Launchpad as well as Windows binaries on GitHub for the latest release version, while Homebrew can be used on macOS to build corresponding packages. Tutorials on our website provide further information on how to develop applications using RL.

These tutorials include instructions on how to

install the latest release on Ubuntu, Windows, or macOS,
create your first program using RL on Linux or Windows,
have a look at our short API overview and our documentation,
create your robot model with a kinematics and geometry definition,
plan a collision-free path in your path planning scenario,
build RL from source on Ubuntu, Windows, or macOS.

Next Steps

RL includes a number of demo [applications](demos) and a selection of [kinematics](examples/rlmdl), [geometry](examples/rlsg), and [path planning](examples/rlplan) examples that demonstrate how to use it for more advanced applications. Due to their size, a larger set of examples can be found in a separate repository.

Among several others, these demo applications include

a tool for [converting](demos/rlRotationConverterDemo) between rotation matrices, angle axis, quaternions, and Euler angles,
the visualization of [collision detection](demos/rlCollisionDemo) queries that can highlight intersections, minimum distance, and penetration depth,
a [kinematics simulator](demos/rlCoachMdl) that uses a TCP port for joint position updates,
a [dynamics simulator](demos/rlSimulator) that listens for joint torque updates,
the calculation of a collision-free path using a [Probabilistic Roadmap](demos/rlPrmDemo) or a [Rapidly-Exploring Random Tree](demos/rlRrtDemo),
the visualization of [path planning](demos/rlPlanDemo) queries based on scenario definitions from an XML file,
robot [forward and inverse dynamics](demos/rlDynamics1Demo) using the Recursive Newton-Euler and Articulated-Body Algorithm methods,
the calculation of [dynamics properties](demos/rlDynamics2Demo) such as mass matrix, centrifugal and Coriolis forces, or gravity compensation,
the calculation and sending of a [trajectory](demos/rlAxisControllerDemo) to a robot controller based on a cubic or quintic polynomial.

Publications

For more detailed information on the design of the Robotics Library, please have a look at our IROS paper. The reference is

Markus Rickert and Andre Gaschler. Robotics Library: An object-oriented approach to robot applications. In Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), pages 733–740, Vancouver, BC, Canada, September 2017.

@InProceedings{Rickert2017a,
  author    = {Markus Rickert and Andre Gaschler},
  title     = {{R}obotics {L}ibrary: An Object-Oriented Approach to Robot Applications},
  booktitle = {Proceedings of the {IEEE}/{RSJ} International Conference on Intelligent Robots and Systems},
  year      = {2017},
  pages     = {733--740},
  address   = {Vancouver, BC, Canada},
  month     = sep,
  doi       = {10.1109/IROS.2017.8202232},
}

License

All source code files of RL are licensed under the permissive [BSD 2-clause license](LICENSE.md). For the licenses of third-party dependencies, please refer to the respective projects.

*Note that all licence references and agreements mentioned in the Robotics Library (RL) README section above are relevant to that project's source code only.