| hls-lfcd-lds-driver |
2.0.4-1 |
ROS package for LDS(HLS-LFCD2). The LDS (Laser Distance Sensor) is a sensor sending the data to Host for the simultaneous localization and mapping (SLAM). Simultaneously the detecting obstacle data can also be sent to Host. HLDS(Hitachi-LG Data Storage) is developing the technology for the moving platform sensor such as Robot Vacuum Cleaners, Home Robot, Robotics Lawn Mower Sensor, etc. |
meta-ros2-galactic |
| ifuse |
1.1.4 |
A fuse filesystem to access the contents of an iPhone or iPod Touch |
meta-filesystems |
| image-geometry |
1.13.0 |
`image_geometry` contains C++ and Python libraries for interpreting images geometrically. It interfaces the calibration parameters in sensor_msgs/CameraInfo messages with OpenCV functions such as image rectification, much as cv_bridge interfaces ROS sensor_msgs/Image with OpenCV data types. |
meta-ros1-melodic |
| image-geometry |
2.1.4-1 |
`image_geometry` contains C++ and Python libraries for interpreting images geometrically. It interfaces the calibration parameters in sensor_msgs/CameraInfo messages with OpenCV functions such as image rectification, much as cv_bridge interfaces ROS sensor_msgs/Image with OpenCV data types. |
meta-ros2-dashing |
| image-geometry |
2.1.4-1 |
`image_geometry` contains C++ and Python libraries for interpreting images geometrically. It interfaces the calibration parameters in sensor_msgs/CameraInfo messages with OpenCV functions such as image rectification, much as cv_bridge interfaces ROS sensor_msgs/Image with OpenCV data types. |
meta-ros2-eloquent |
| image-geometry |
2.2.1-1 |
`image_geometry` contains C++ and Python libraries for interpreting images geometrically. It interfaces the calibration parameters in sensor_msgs/CameraInfo messages with OpenCV functions such as image rectification, much as cv_bridge interfaces ROS sensor_msgs/Image with OpenCV data types. |
meta-ros2-foxy |
| image-geometry |
2.2.1-1 |
`image_geometry` contains C++ and Python libraries for interpreting images geometrically. It interfaces the calibration parameters in sensor_msgs/CameraInfo messages with OpenCV functions such as image rectification, much as cv_bridge interfaces ROS sensor_msgs/Image with OpenCV data types. |
meta-ros2-rolling |
| image-geometry |
1.15.0-1 |
`image_geometry` contains C++ and Python libraries for interpreting images geometrically. It interfaces the calibration parameters in sensor_msgs/CameraInfo messages with OpenCV functions such as image rectification, much as cv_bridge interfaces ROS sensor_msgs/Image with OpenCV data types. |
meta-ros1-noetic |
| image-geometry |
2.2.1-2 |
`image_geometry` contains C++ and Python libraries for interpreting images geometrically. It interfaces the calibration parameters in sensor_msgs/CameraInfo messages with OpenCV functions such as image rectification, much as cv_bridge interfaces ROS sensor_msgs/Image with OpenCV data types. |
meta-ros2-galactic |
| image-rotate |
1.15.0-1 |
<p> Contains a node that rotates an image stream in a way that minimizes the angle between a vector in some arbitrary frame and a vector in the camera frame. The frame of the outgoing image is published by the node. </p> <p> This node is intended to allow camera images to be visualized in an orientation that is more intuitive than the hardware-constrained orientation of the physical camera. This is particularly helpful, for example, to show images from the PR2's forearm cameras with a consistent up direction, despite the fact that the forearms need to rotate in arbitrary ways during manipulation. </p> <p> It is not recommended to use the output from this node for further computation, as it interpolates the source image, introduces black borders, and does not output a camera_info. </p> |
meta-ros1-melodic |
| image-rotate |
2.1.1-1 |
<p> Contains a node that rotates an image stream in a way that minimizes the angle between a vector in some arbitrary frame and a vector in the camera frame. The frame of the outgoing image is published by the node. </p> <p> This node is intended to allow camera images to be visualized in an orientation that is more intuitive than the hardware-constrained orientation of the physical camera. This is particularly helpful, for example, to show images from the PR2's forearm cameras with a consistent up direction, despite the fact that the forearms need to rotate in arbitrary ways during manipulation. </p> <p> It is not recommended to use the output from this node for further computation, as it interpolates the source image, introduces black borders, and does not output a camera_info. </p> |
meta-ros2-dashing |
| image-rotate |
2.2.1-1 |
<p> Contains a node that rotates an image stream in a way that minimizes the angle between a vector in some arbitrary frame and a vector in the camera frame. The frame of the outgoing image is published by the node. </p> <p> This node is intended to allow camera images to be visualized in an orientation that is more intuitive than the hardware-constrained orientation of the physical camera. This is particularly helpful, for example, to show images from the PR2's forearm cameras with a consistent up direction, despite the fact that the forearms need to rotate in arbitrary ways during manipulation. </p> <p> It is not recommended to use the output from this node for further computation, as it interpolates the source image, introduces black borders, and does not output a camera_info. </p> |
meta-ros2-foxy |
| image-rotate |
2.2.1-2 |
<p> Contains a node that rotates an image stream in a way that minimizes the angle between a vector in some arbitrary frame and a vector in the camera frame. The frame of the outgoing image is published by the node. </p> <p> This node is intended to allow camera images to be visualized in an orientation that is more intuitive than the hardware-constrained orientation of the physical camera. This is particularly helpful, for example, to show images from the PR2's forearm cameras with a consistent up direction, despite the fact that the forearms need to rotate in arbitrary ways during manipulation. </p> <p> It is not recommended to use the output from this node for further computation, as it interpolates the source image, introduces black borders, and does not output a camera_info. </p> |
meta-ros2-rolling |
| image-rotate |
1.15.3-1 |
<p> Contains a node that rotates an image stream in a way that minimizes the angle between a vector in some arbitrary frame and a vector in the camera frame. The frame of the outgoing image is published by the node. </p> <p> This node is intended to allow camera images to be visualized in an orientation that is more intuitive than the hardware-constrained orientation of the physical camera. This is particularly helpful, for example, to show images from the PR2's forearm cameras with a consistent up direction, despite the fact that the forearms need to rotate in arbitrary ways during manipulation. </p> <p> It is not recommended to use the output from this node for further computation, as it interpolates the source image, introduces black borders, and does not output a camera_info. </p> |
meta-ros1-noetic |
| image-rotate |
2.2.1-3 |
<p> Contains a node that rotates an image stream in a way that minimizes the angle between a vector in some arbitrary frame and a vector in the camera frame. The frame of the outgoing image is published by the node. </p> <p> This node is intended to allow camera images to be visualized in an orientation that is more intuitive than the hardware-constrained orientation of the physical camera. This is particularly helpful, for example, to show images from the PR2's forearm cameras with a consistent up direction, despite the fact that the forearms need to rotate in arbitrary ways during manipulation. </p> <p> It is not recommended to use the output from this node for further computation, as it interpolates the source image, introduces black borders, and does not output a camera_info. </p> |
meta-ros2-galactic |
| image-transport-plugins |
1.9.5 |
A set of plugins for publishing and subscribing to sensor_msgs/Image topics in representations other than raw pixel data. For example, for viewing a stream of images off-robot, a video codec will give much lower bandwidth and latency. For low frame rate tranport of high-definition images, you might prefer sending them as JPEG or PNG-compressed form. |
meta-ros1-melodic |
| image-transport-plugins |
2.1.0-1 |
A set of plugins for publishing and subscribing to sensor_msgs/Image topics in representations other than raw pixel data. For example, for viewing a stream of images off-robot, a video codec will give much lower bandwidth and latency. For low frame rate tranport of high-definition images, you might prefer sending them as JPEG or PNG-compressed form. |
meta-ros2-dashing |
| image-transport-plugins |
2.2.1-1 |
A set of plugins for publishing and subscribing to sensor_msgs/Image topics in representations other than raw pixel data. For example, for viewing a stream of images off-robot, a video codec will give much lower bandwidth and latency. For low frame rate tranport of high-definition images, you might prefer sending them as JPEG or PNG-compressed form. |
meta-ros2-eloquent |
| image-transport-plugins |
2.3.1-1 |
A set of plugins for publishing and subscribing to sensor_msgs/Image topics in representations other than raw pixel data. For example, for viewing a stream of images off-robot, a video codec will give much lower bandwidth and latency. For low frame rate tranport of high-definition images, you might prefer sending them as JPEG or PNG-compressed form. |
meta-ros2-foxy |
| image-transport-plugins |
2.3.1-1 |
A set of plugins for publishing and subscribing to sensor_msgs/Image topics in representations other than raw pixel data. For example, for viewing a stream of images off-robot, a video codec will give much lower bandwidth and latency. For low frame rate tranport of high-definition images, you might prefer sending them as JPEG or PNG-compressed form. |
meta-ros2-rolling |
| image-transport-plugins |
1.14.0-1 |
A set of plugins for publishing and subscribing to sensor_msgs/Image topics in representations other than raw pixel data. For example, for viewing a stream of images off-robot, a video codec will give much lower bandwidth and latency. For low frame rate tranport of high-definition images, you might prefer sending them as JPEG or PNG-compressed form. |
meta-ros1-noetic |
| image-transport-plugins |
2.3.1-1 |
A set of plugins for publishing and subscribing to sensor_msgs/Image topics in representations other than raw pixel data. For example, for viewing a stream of images off-robot, a video codec will give much lower bandwidth and latency. For low frame rate tranport of high-definition images, you might prefer sending them as JPEG or PNG-compressed form. |
meta-ros2-galactic |
| inetutils |
2.0 |
The GNU inetutils are a collection of common networking utilities and servers including ftp, ftpd, rcp, rexec, rlogin, rlogind, rsh, rshd, syslog, syslogd, talk, talkd, telnet, telnetd, tftp, tftpd, and uucpd. |
openembedded-core |
| initscripts |
1.0 |
SysV init scripts |
openembedded-core |
| intel-microcode |
20220207 |
Intel Processor Microcode Datafile for Linux |
meta-intel |
| ipmitool |
1.8.18 |
Utility for IPMI control |
meta-oe |
| ipmitool |
1.8.19+gitX |
Utility for IPMI control |
meta-tanowrt |
| irda-utils |
0.9.18 |
Common files for IrDA |
meta-oe |
| jaxen |
1.1.6 |
XPath library written in Java |
meta-java |
| jdom |
1.1.3 |
Parses, manipulates, and outputs XML using standard Java constructs |
meta-java |
| jq |
1.6 |
Lightweight and flexible command-line JSON processor |
meta-oe |
| json-c |
0.15 |
C bindings for apps which will manipulate JSON data |
openembedded-core |
| json-glib |
1.6.2 |
JSON-GLib implements a full JSON parser using GLib and GObject |
openembedded-core |
| k3s |
v1.20.11+k3s2 |
Production-Grade Container Scheduling and Management |
meta-virtualization |
| katomic |
21.04.3 |
Katomic is a fun and educational game built around molecular geometry |
meta-qt5-extra |
| kcachegrind |
21.04.3 |
GUI to profilers such as Valgrind |
meta-qt5-extra |
| kconfig-frontends |
4.11.0.1 |
Linux kernel style configuration framework for other projects |
meta-oe |
| kdl-parser |
1.13.1 |
The Kinematics and Dynamics Library (KDL) defines a tree structure to represent the kinematic and dynamic parameters of a robot mechanism. <tt>kdl_parser</tt> provides tools to construct a KDL tree from an XML robot representation in URDF. |
meta-ros1-melodic |
| kdl-parser |
2.2.1-1 |
The Kinematics and Dynamics Library (KDL) defines a tree structure to represent the kinematic and dynamic parameters of a robot mechanism. <tt>kdl_parser</tt> provides tools to construct a KDL tree from an XML robot representation in URDF. |
meta-ros2-dashing |
| kdl-parser |
2.2.1-1 |
The Kinematics and Dynamics Library (KDL) defines a tree structure to represent the kinematic and dynamic parameters of a robot mechanism. <tt>kdl_parser</tt> provides tools to construct a KDL tree from an XML robot representation in URDF. |
meta-ros2-eloquent |
| kdl-parser |
2.4.1-2 |
The Kinematics and Dynamics Library (KDL) defines a tree structure to represent the kinematic and dynamic parameters of a robot mechanism. <tt>kdl_parser</tt> provides tools to construct a KDL tree from an XML robot representation in URDF. |
meta-ros2-foxy |
| kdl-parser |
2.5.0-1 |
The Kinematics and Dynamics Library (KDL) defines a tree structure to represent the kinematic and dynamic parameters of a robot mechanism. <tt>kdl_parser</tt> provides tools to construct a KDL tree from an XML robot representation in URDF. |
meta-ros2-rolling |
| kdl-parser |
1.14.1-1 |
The Kinematics and Dynamics Library (KDL) defines a tree structure to represent the kinematic and dynamic parameters of a robot mechanism. <tt>kdl_parser</tt> provides tools to construct a KDL tree from an XML robot representation in URDF. |
meta-ros1-noetic |
| kdl-parser |
2.5.0-2 |
The Kinematics and Dynamics Library (KDL) defines a tree structure to represent the kinematic and dynamic parameters of a robot mechanism. <tt>kdl_parser</tt> provides tools to construct a KDL tree from an XML robot representation in URDF. |
meta-ros2-galactic |
| kdl-parser-py |
1.13.1 |
The Kinematics and Dynamics Library (KDL) defines a tree structure to represent the kinematic and dynamic parameters of a robot mechanism. <tt>kdl_parser_py</tt> provides Python tools to construct a KDL tree from an XML robot representation in URDF. |
meta-ros1-melodic |
| kdl-parser-py |
1.14.1-1 |
The Kinematics and Dynamics Library (KDL) defines a tree structure to represent the kinematic and dynamic parameters of a robot mechanism. <tt>kdl_parser_py</tt> provides Python tools to construct a KDL tree from an XML robot representation in URDF. |
meta-ros1-noetic |
| keepalived |
2.2.1 |
High Availability monitor built upon LVS, VRRP and service pollers |
meta-networking |
| keepalived |
2.2.4 |
High Availability monitor built upon LVS, VRRP and service pollers |
meta-tanowrt |
| kinesis-manager |
2.0.3-1 |
AWS Kinesis stream management library intended for use with the Kinesis Video Producer SDK |
meta-ros1-melodic |
| kinesis-manager |
2.0.1-1 |
AWS Kinesis stream management library intended for use with the Kinesis Video Producer SDK |
meta-ros2-dashing |