| nav2-smoother |
1.3.11-1 |
Smoother action interface |
meta-ros2-jazzy |
| nav2-smoother |
1.4.2-1 |
Smoother action interface |
meta-ros2-kilted |
| nav2-system-tests |
0.2.6-1 |
TODO |
meta-ros2-dashing |
| nav2-system-tests |
0.3.5-1 |
TODO |
meta-ros2-eloquent |
| nav2-system-tests |
0.4.7-1 |
TODO |
meta-ros2-foxy |
| nav2-system-tests |
1.0.7-1 |
TODO |
meta-ros2-galactic |
| nav2-system-tests |
1.1.20-1 |
TODO |
meta-ros2-humble |
| nav2-system-tests |
1.3.11-1 |
A sets of system-level tests for Nav2 usually involving full robot simulation |
meta-ros2-jazzy |
| nav2-system-tests |
1.4.2-1 |
A sets of system-level tests for Nav2 usually involving full robot simulation |
meta-ros2-kilted |
| nav2-theta-star-planner |
1.0.7-1 |
Theta* Global Planning Plugin |
meta-ros2-galactic |
| nav2-theta-star-planner |
1.1.20-1 |
Theta* Global Planning Plugin |
meta-ros2-humble |
| nav2-theta-star-planner |
1.3.11-1 |
Theta* Global Planning Plugin |
meta-ros2-jazzy |
| nav2-theta-star-planner |
1.4.2-1 |
Theta* Global Planning Plugin |
meta-ros2-kilted |
| nav2-util |
0.2.6-1 |
TODO |
meta-ros2-dashing |
| nav2-util |
0.3.5-1 |
TODO |
meta-ros2-eloquent |
| nav2-util |
0.4.7-1 |
TODO |
meta-ros2-foxy |
| nav2-util |
1.0.7-1 |
TODO |
meta-ros2-galactic |
| nav2-util |
1.1.20-1 |
TODO |
meta-ros2-humble |
| nav2-util |
1.3.11-1 |
Nav2 utilities |
meta-ros2-jazzy |
| nav2-util |
1.4.2-1 |
Nav2 utilities |
meta-ros2-kilted |
| nav2-velocity-smoother |
1.1.20-1 |
Nav2's Output velocity smoother |
meta-ros2-humble |
| nav2-velocity-smoother |
1.3.11-1 |
Nav2's Output velocity smoother |
meta-ros2-jazzy |
| nav2-velocity-smoother |
1.4.2-1 |
Nav2's Output velocity smoother |
meta-ros2-kilted |
| nav2-voxel-grid |
0.2.6-1 |
voxel_grid provides an implementation of an efficient 3D voxel grid. The occupancy grid can support 3 different representations for the state of a cell: marked, free, or unknown. Due to the underlying implementation relying on bitwise and and or integer operations, the voxel grid only supports 16 different levels per voxel column. However, this limitation yields raytracing and cell marking performance in the grid comparable to standard 2D structures making it quite fast compared to most 3D structures. |
meta-ros2-dashing |
| nav2-voxel-grid |
0.3.5-1 |
voxel_grid provides an implementation of an efficient 3D voxel grid. The occupancy grid can support 3 different representations for the state of a cell: marked, free, or unknown. Due to the underlying implementation relying on bitwise and and or integer operations, the voxel grid only supports 16 different levels per voxel column. However, this limitation yields raytracing and cell marking performance in the grid comparable to standard 2D structures making it quite fast compared to most 3D structures. |
meta-ros2-eloquent |
| nav2-voxel-grid |
0.4.7-1 |
voxel_grid provides an implementation of an efficient 3D voxel grid. The occupancy grid can support 3 different representations for the state of a cell: marked, free, or unknown. Due to the underlying implementation relying on bitwise and and or integer operations, the voxel grid only supports 16 different levels per voxel column. However, this limitation yields raytracing and cell marking performance in the grid comparable to standard 2D structures making it quite fast compared to most 3D structures. |
meta-ros2-foxy |
| nav2-voxel-grid |
1.0.7-1 |
voxel_grid provides an implementation of an efficient 3D voxel grid. The occupancy grid can support 3 different representations for the state of a cell: marked, free, or unknown. Due to the underlying implementation relying on bitwise and and or integer operations, the voxel grid only supports 16 different levels per voxel column. However, this limitation yields raytracing and cell marking performance in the grid comparable to standard 2D structures making it quite fast compared to most 3D structures. |
meta-ros2-galactic |
| nav2-voxel-grid |
1.1.20-1 |
voxel_grid provides an implementation of an efficient 3D voxel grid. The occupancy grid can support 3 different representations for the state of a cell: marked, free, or unknown. Due to the underlying implementation relying on bitwise and and or integer operations, the voxel grid only supports 16 different levels per voxel column. However, this limitation yields raytracing and cell marking performance in the grid comparable to standard 2D structures making it quite fast compared to most 3D structures. |
meta-ros2-humble |
| nav2-voxel-grid |
1.3.11-1 |
voxel_grid provides an implementation of an efficient 3D voxel grid. The occupancy grid can support 3 different representations for the state of a cell: marked, free, or unknown. Due to the underlying implementation relying on bitwise and and or integer operations, the voxel grid only supports 16 different levels per voxel column. However, this limitation yields raytracing and cell marking performance in the grid comparable to standard 2D structures making it quite fast compared to most 3D structures. |
meta-ros2-jazzy |
| nav2-voxel-grid |
1.4.2-1 |
voxel_grid provides an implementation of an efficient 3D voxel grid. The occupancy grid can support 3 different representations for the state of a cell: marked, free, or unknown. Due to the underlying implementation relying on bitwise and and or integer operations, the voxel grid only supports 16 different levels per voxel column. However, this limitation yields raytracing and cell marking performance in the grid comparable to standard 2D structures making it quite fast compared to most 3D structures. |
meta-ros2-kilted |
| nav2-waypoint-follower |
0.3.5-1 |
A waypoint follower navigation server |
meta-ros2-eloquent |
| nav2-waypoint-follower |
0.4.7-1 |
A waypoint follower navigation server |
meta-ros2-foxy |
| nav2-waypoint-follower |
1.0.7-1 |
A waypoint follower navigation server |
meta-ros2-galactic |
| nav2-waypoint-follower |
1.1.20-1 |
A waypoint follower navigation server |
meta-ros2-humble |
| nav2-waypoint-follower |
1.3.11-1 |
A waypoint follower navigation server |
meta-ros2-jazzy |
| nav2-waypoint-follower |
1.4.2-1 |
A waypoint follower navigation server |
meta-ros2-kilted |
| nav2-world-model |
0.2.6-1 |
TODO |
meta-ros2-dashing |
| nav2d |
0.4.2 |
Meta-Package containing modules for 2D-Navigation |
meta-ros1-melodic |
| nav2d |
0.4.3-1 |
Meta-Package containing modules for 2D-Navigation |
meta-ros1-noetic |
| nav2d-exploration |
0.4.2 |
This package holds a collection of plugins for the RobotNavigator, that provide different cooperative exploration strategies for a team of mobile robots. |
meta-ros1-melodic |
| nav2d-exploration |
0.4.3-1 |
This package holds a collection of plugins for the RobotNavigator, that provide different cooperative exploration strategies for a team of mobile robots. |
meta-ros1-noetic |
| nav2d-karto |
0.4.2 |
Graph-based Simultaneous Localization and Mapping module. Includes OpenKarto GraphSLAM library by "SRI International". |
meta-ros1-melodic |
| nav2d-karto |
0.4.3-1 |
Graph-based Simultaneous Localization and Mapping module. Includes OpenKarto GraphSLAM library by "SRI International". |
meta-ros1-noetic |
| nav2d-localizer |
0.4.2 |
Wrapper around Particle Filter implementation. The SelfLocalizer can be used as library or as a ros-node. |
meta-ros1-melodic |
| nav2d-localizer |
0.4.3-1 |
Wrapper around Particle Filter implementation. The SelfLocalizer can be used as library or as a ros-node. |
meta-ros1-noetic |
| nav2d-msgs |
0.4.2 |
Messages used for 2D-Navigation. |
meta-ros1-melodic |
| nav2d-msgs |
0.4.3-1 |
Messages used for 2D-Navigation. |
meta-ros1-noetic |
| nav2d-navigator |
0.4.2 |
This package provides a node for higher level navigation of a mobile robot in a planar environment. It needs a map and the robot's position within this map to create a plan for navigation. When used together with a SLAM module it can also be used to perform autonomous exploration of the robot's workspace. |
meta-ros1-melodic |
| nav2d-navigator |
0.4.3-1 |
This package provides a node for higher level navigation of a mobile robot in a planar environment. It needs a map and the robot's position within this map to create a plan for navigation. When used together with a SLAM module it can also be used to perform autonomous exploration of the robot's workspace. |
meta-ros1-noetic |
| 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 |