| chomp-motion-planner |
1.0.2-1 |
chomp_motion_planner |
meta-ros1-melodic |
| pilz-industrial-motionblacklisted |
0.4.10-1 |
The pilz_industrial_motion package |
meta-ros1-melodic |
| pilz-industrial-motion-testutilsblacklisted |
0.4.10-1 |
Helper scripts and functionality to test industrial motion generation |
meta-ros1-melodic |
| abb-irb2400-moveit-configblacklisted |
1.3.1-1 |
<p> MoveIt package for the ABB IRB 2400. </p> <p> An automatically generated package with all the configuration and launch files for using the ABB IRB 2400 with the MoveIt Motion Planning Framework. </p> |
meta-ros1-melodic |
| abb-irb2400-supportblacklisted |
1.3.1-1 |
<p> ROS-Industrial support for the ABB IRB 2400 (and variants). </p> <p> This package contains configuration data, 3D models and launch files for ABB IRB 2400 manipulators. This currently includes the base model. </p> <p> Joint limits and max joint velocities are based on the information in the ABB data sheets. All URDFs / XACROs are based on the default motion and joint velocity limits, unless noted otherwise (ie: no support for high speed joints, extended / limited motion ranges or other options). </p> <p> Before using any of the configuration files and / or meshes included in this package, be sure to check they are correct for the particular robot model and configuration you intend to use them with. </p> <p> The unqualified IRB 2400 model will be removed in ROS-Lunar, please use the IRB 2400-12/1.55 as a replacement. </p> |
meta-ros1-melodic |
| abb-irb4400-supportblacklisted |
1.3.1-1 |
<p> ROS-Industrial support for the ABB IRB 4400 (and variants). </p> <p> This package contains configuration data, 3D models and launch files for ABB IRB 4400 manipulators. This currently includes the L30. </p> <p> Joint limits and max joint velocities are based on the information in the <a href="http://www05.abb.com/global/scot/scot352.nsf/veritydisplay/c90b98aaa057bd6ec12576cb00528ef6/$file/Product%20specification%204400%20M99%20BWOS3.2.pdf"> ABB IRB 4400 product specification document</a> (Article No: 3HAC 8770-1). All urdfs / xacros are based on the default motion and joint velocity limits, unless noted otherwise (ie: no support for high speed joints, extended / limited motion ranges or other options). </p> <p> Before using any of the configuration files and / or meshes included in this package, be sure to check they are correct for the particular robot model and configuration you intend to use them with. </p> |
meta-ros1-melodic |
| abb-irb5400-supportblacklisted |
1.3.1-1 |
<p> ROS-Industrial support for the ABB IRB 5400 (and variants). </p> <p> This package contains configuration data, 3D models and launch files for ABB IRB 5400 manipulators. This currently includes the base model. </p> <p> Joint limits and max joint velocities are based on the information in the ABB data sheets. All URDFs / XACROs are based on the default motion and joint velocity limits, unless noted otherwise (ie: no support for high speed joints, extended / limited motion ranges or other options). </p> <p> Before using any of the configuration files and / or meshes included in this package, be sure to check they are correct for the particular robot model and configuration you intend to use them with. </p> |
meta-ros1-melodic |
| abb-irb6600-supportblacklisted |
1.3.1-1 |
<p> ROS-Industrial support for the ABB IRB 6600 (and variants). </p> <p> This package contains configuration data, 3D models and launch files for ABB IRB 6600 manipulators. This currently includes the base model. </p> <p> Joint limits and max joint velocities are based on the information in the ABB data sheets. All URDFs / XACROs are based on the default motion and joint velocity limits, unless noted otherwise (ie: no support for high speed joints, extended / limited motion ranges or other options). </p> <p> Before using any of the configuration files and / or meshes included in this package, be sure to check they are correct for the particular robot model and configuration you intend to use them with. </p> <p> The unqualified IRB 6400 model will be removed in ROS-Lunar, please use the abb_irb6640_support as a replacement. </p> |
meta-ros1-melodic |
| abb-irb6640-moveit-configblacklisted |
1.3.1-1 |
<p> MoveIt package for the ABB IRB 6640. </p> <p> An automatically generated package with all the configuration and launch files for using the ABB IRB 6640 with the MoveIt Motion Planning Framework. </p> |
meta-ros1-melodic |
| abb-irb6640-supportblacklisted |
1.3.1-1 |
<p> ROS-Industrial support for the ABB IRB 6640 (and variants). </p> <p> This package contains configuration data, 3D models and launch files for ABB IRB 6640 manipulators. This currently includes the IRB 6640-185/2.8m (6640-185) only. </p> <p> Joint limits and max joint velocities are based on the information in the <a href="http://www.abbrobots.co.uk/en/3HAC028284-en.pdf">ABB IRB 6640 technical data sheet</a> (Version: 3HAC 028284-001 Rev. N). All urdfs / xacros are based on the default motion and joint velocity limits, unless noted otherwise (ie: no support for high speed joints, extended / limited motion ranges or other options). </p> <p> Before using any of the configuration files and / or meshes included in this package, be sure to check they are correct for the particular robot model and configuration you intend to use them with. </p> |
meta-ros1-melodic |
| angles |
1.9.12-1 |
This package provides a set of simple math utilities to work with angles. The utilities cover simple things like normalizing an angle and conversion between degrees and radians. But even if you're trying to calculate things like the shortest angular distance between two joint space positions of your robot, but the joint motion is constrained by joint limits, this package is what you need. The code in this package is stable and well tested. There are no plans for major changes in the near future. |
meta-ros1-melodic |
| angles |
1.12.2-1 |
This package provides a set of simple math utilities to work with angles. The utilities cover simple things like normalizing an angle and conversion between degrees and radians. But even if you're trying to calculate things like the shortest angular distance between two joint space positions of your robot, but the joint motion is constrained by joint limits, this package is what you need. The code in this package is stable and well tested. There are no plans for major changes in the near future. |
meta-ros2-dashing |
| angles |
1.12.2-1 |
This package provides a set of simple math utilities to work with angles. The utilities cover simple things like normalizing an angle and conversion between degrees and radians. But even if you're trying to calculate things like the shortest angular distance between two joint space positions of your robot, but the joint motion is constrained by joint limits, this package is what you need. The code in this package is stable and well tested. There are no plans for major changes in the near future. |
meta-ros2-eloquent |
| angles |
1.12.3-1 |
This package provides a set of simple math utilities to work with angles. The utilities cover simple things like normalizing an angle and conversion between degrees and radians. But even if you're trying to calculate things like the shortest angular distance between two joint space positions of your robot, but the joint motion is constrained by joint limits, this package is what you need. The code in this package is stable and well tested. There are no plans for major changes in the near future. |
meta-ros2-foxy |
| canopen-402blacklisted |
0.8.2-1 |
This implements the CANopen device profile for drives and motion control. CiA(r) 402 |
meta-ros1-melodic |
| cob-base-drive-chainblacklisted |
0.7.1-1 |
This package contains classes that are able to control the platform of the Care-O-Bot. This means to establish a CAN communication to drive and steering motors of the platform and later send motion commands and receive motor information. |
meta-ros1-melodic |
| cob-undercarriage-ctrl |
0.7.1-1 |
cob_undercarriage_ctrl implements a controller for the omnidirectional base of Care-O-bot 3 on joint level. For a given Pltf-Twist the according wheel steering angles and linear wheel velocities are calculated based on the principle of rigid body motion. Each joint is than controlled individually to achieve the computed position and velocity |
meta-ros1-melodic |
| exoticablacklisted |
5.1.3-3 |
The Extensible Optimization Toolset (EXOTica) is a library for defining problems for robot motion planning. This package serves similar to a metapackage and contains dependencies onto all core-released exotica packages. It also builds the documentation. |
meta-ros1-melodic |
| exotica-coreblacklisted |
5.1.3-3 |
The Extensible Optimization Toolset (EXOTica) is a library for defining problems for robot motion planning. |
meta-ros1-melodic |
| exotica-ompl-solverblacklisted |
5.1.3-3 |
Exotica solvers based on the Open Motion Planning Libary (OMPL) |
meta-ros1-melodic |
| fetch-moveit-configblacklisted |
0.8.2-1 |
An automatically generated package with all the configuration and launch files for using the fetch_urdf with the MoveIt Motion Planning Framework |
meta-ros1-melodic |
| fetch-simple-linear-controller |
0.0.1-1 |
Position feedback controller for simple linear motion of the fetch robot's end-effector. |
meta-ros1-melodic |
| fsrobo-r-moveit-configblacklisted |
0.7.1-1 |
An automatically generated package with all the configuration and launch files for using the fsrobo_r with the MoveIt! Motion Planning Framework |
meta-ros1-melodic |
| hector-mapping |
0.4.0-1 |
hector_mapping is a SLAM approach that can be used without odometry as well as on platforms that exhibit roll/pitch motion (of the sensor, the platform or both). It leverages the high update rate of modern LIDAR systems like the Hokuyo UTM-30LX and provides 2D pose estimates at scan rate of the sensors (40Hz for the UTM-30LX). While the system does not provide explicit loop closing ability, it is sufficiently accurate for many real world scenarios. The system has successfully been used on Unmanned Ground Robots, Unmanned Surface Vehicles, Handheld Mapping Devices and logged data from quadrotor UAVs. |
meta-ros1-melodic |
| image-publisher |
1.14.0-1 |
<p> Contains a node publish an image stream from single image file or avi motion file. </p> |
meta-ros1-melodic |
| image-publisherblacklisted |
2.1.1-1 |
<p> Contains a node publish an image stream from single image file or avi motion file. </p> |
meta-ros2-foxy |
| invensense |
4.2+gitrX |
The Motion Library from Invensense processes gyroscopes and accelerometers to provide a physical model of the movement of the sensors. |
meta-android |
| libxvmc |
1.0.10 |
XvMC: X Video Motion Compensation extension library |
openembedded-core |
| nav2d-operator |
0.4.2 |
The operator is a lightweight, purely reactive obstacle-avoidance module for mobile robots moving in a planar environment. The operator node works by evaluating a set of predefined motion primitives based on a local costmap and a desired direction. The best evaluated motion command will be send to the mobile base. |
meta-ros1-melodic |
| ompl |
1.4.2-5 |
OMPL is a free sampling-based motion planning library. |
meta-ros1-melodic |
| ompl |
1.4.2-2 |
OMPL is a free sampling-based motion planning library. |
meta-ros2-dashing |
| ompl |
1.5.0-1 |
OMPL is a free sampling-based motion planning library. |
meta-ros2-foxy |
| open-manipulator-moveitblacklisted |
2.0.1 |
An automatically generated package with all the configuration and launch files for using the open_manipulator with the MoveIt! Motion Planning Framework |
meta-ros1-melodic |
| open-manipulator-with-tb3-waffle-moveitblacklisted |
1.1.0-2 |
An automatically generated package with all the configuration and launch files for using the om_with_tb3 with the MoveIt! Motion Planning Framework |
meta-ros1-melodic |
| open-manipulator-with-tb3-waffle-pi-moveitblacklisted |
1.1.0-2 |
An automatically generated package with all the configuration and launch files for using the om_with_tb3 with the MoveIt! Motion Planning Framework |
meta-ros1-melodic |
| panda-moveit-configblacklisted |
0.7.3-1 |
An automatically generated package with all the configuration and launch files for using the panda with the MoveIt! Motion Planning Framework |
meta-ros1-melodic |
| pr2-moveit-configblacklisted |
0.7.3-1 |
An automatically generated package with all the configuration and launch files for using the pr2 with the MoveIt Motion Planning Framework |
meta-ros1-melodic |
| prbt-moveit-configblacklisted |
0.5.14-1 |
An automatically generated package with all the configuration and launch files for using the prbt with the MoveIt! Motion Planning Framework |
meta-ros1-melodic |
| rc-dynamics-apiblacklisted |
0.10.0-1 |
The rc_dynamics_api provides an API for easy handling of the dynamic-state data streams provided by Roboception's stereo camera with self-localization. See http://rc-visard.com Dynamic-state estimates of the rc_visard relate to its self-localization and ego-motion estimation. These states refer to rc_visard's current pose, velocity, or acceleration and are published on demand via several data streams. For a complete list and descriptions of these dynamics states and the respective data streams please refer to rc_visard's user manual. |
meta-ros1-melodic |
| rqt-moveitblacklisted |
0.5.7 |
An rqt-based tool that assists monitoring tasks for <a href="http://ros.org/wiki/moveit">MoveIt!</a> motion planner developers and users. Currently the following items are monitored if they are either running, existing or published: <ul> <li>Node: /move_group</li> <li>Parameter: [/robot_description, /robot_description_semantic]</li> <li>Topic: Following types are monitored. Published "names" are ignored.<br/> [sensor_msgs/PointCloud, sensor_msgs/PointCloud2, sensor_msgs/Image, sensor_msgs/CameraInfo]</li> </ul> Since this package is not made by the MoveIt! development team (although with assistance from the them), please post issue reports to the designated tracker (not MoveIt!'s main tracker). |
meta-ros1-melodic |
| safety-limiter |
0.8.1-1 |
Motion limiter package for collision prevention |
meta-ros1-melodic |
| seed-r7-typef-moveit-configblacklisted |
0.3.3-1 |
An automatically generated package with all the configuration and launch files for using the SEED-Noid-Mover-typeF with the MoveIt! Motion Planning Framework |
meta-ros1-melodic |
| towrblacklisted |
1.4.1 |
A light-weight, Eigen-based C++ library for trajectory optimization for legged robots. This library provides implementations for variables, costs and constraints that can be used to represent a legged locomotion problem. The resulting Nonlinear Programming Problem (NLP) can then be solved with off-the-shelf solvers, e.g. Ipopt using the generic optimizer interface <a href="http://wiki.ros.org/ifopt">ifopt</a>. |
meta-ros1-melodic |
| towr-rosblacklisted |
1.4.1 |
A ROS dependent wrapper for <a href="http://wiki.ros.org/towr">towr</a>. Adds a keyboard user interface to set different goal states, motions and robots and visualizes the produced motions plan in rviz using <a href="http://wiki.ros.org/xpp">xpp</a>. |
meta-ros1-melodic |
| wiimoteblacklisted |
1.13.0-1 |
The wiimote package allows ROS nodes to communicate with a Nintendo Wiimote and its related peripherals, including the Nunchuk, Motion Plus, and (experimentally) the Classic. The package implements a ROS node that uses Bluetooth to communicate with the Wiimote device, obtaining accelerometer and gyro data, the state of LEDs, the IR camera, rumble (vibrator), buttons, joystick, and battery state. The node additionally enables ROS nodes to control the Wiimote's LEDs and vibration for feedback to the human Wiimote operator. LEDs and vibration may be switched on and off, or made to operate according to a timed pattern. |
meta-ros1-melodic |
| xpp |
1.0.10 |
Visualization of motion-plans for legged robots. It draws support areas, contact forces and motion trajectories in RVIZ and displays URDFs for specific robots, including a one-legged, a two-legged hopper and <a href="http://dls.iit.it/">HyQ</a>. Example motions were generated by <a href="https://github.com/ethz-adrl/towr">towr</a>. |
meta-ros1-melodic |
| xpp-hyq |
1.0.10 |
HyQ-robot specific functions for visualization in the XPP Motion Framework. These include inverse kinematics as well as urdf files for a one-legged, two-legged and four legged robot with <a href="http://dls.iit.it/">HyQ</a> legs. The dynamic model can be found <a href="https://github.com/iit-DLSLab/hyq-description">here</a>. See also <a href="https://dls.iit.it">IIT</a>. |
meta-ros1-melodic |
| xpp-states |
1.0.10 |
Common definitions (positions, velocities, angular angles, angular rates) and robot definitions in Cartesian and joint state used in the Xpp Motion Framework, as well as conversions to/from xpp_msgs. |
meta-ros1-melodic |
| xpp-vis |
1.0.10 |
Visualization for the XPP Motion Framework. |
meta-ros1-melodic |
| ypspur |
1.17.1-1 |
YP-Spur is a mobile robot motion control software with coordinate frame based commands. |
meta-ros1-melodic |