| image-pipeline |
1.17.0-1 |
image_pipeline fills the gap between getting raw images from a camera driver and higher-level vision processing. |
meta-ros1-noetic |
| image-pipeline |
3.0.9-1 |
image_pipeline fills the gap between getting raw images from a camera driver and higher-level vision processing. |
meta-ros2-humble |
| image-pipeline |
5.0.11-1 |
image_pipeline fills the gap between getting raw images from a camera driver and higher-level vision processing. |
meta-ros2-jazzy |
| image-pipeline |
6.0.11-1 |
image_pipeline fills the gap between getting raw images from a camera driver and higher-level vision processing. |
meta-ros2-kilted |
| image-proc |
7.1.3-1 |
Single image rectification and color processing. |
meta-ros2-rolling |
| image-proc |
1.17.0-1 |
Single image rectification and color processing. |
meta-ros1-noetic |
| image-proc |
3.0.9-1 |
Single image rectification and color processing. |
meta-ros2-humble |
| image-proc |
5.0.11-1 |
Single image rectification and color processing. |
meta-ros2-jazzy |
| image-proc |
6.0.11-1 |
Single image rectification and color processing. |
meta-ros2-kilted |
| image-publisher |
7.1.3-1 |
Contains a node publish an image stream from single image file or avi motion file. |
meta-ros2-rolling |
| image-publisher |
1.17.0-1 |
<p> Contains a node publish an image stream from single image file or avi motion file. </p> |
meta-ros1-noetic |
| image-publisher |
3.0.9-1 |
Contains a node publish an image stream from single image file or avi motion file. |
meta-ros2-humble |
| image-publisher |
5.0.11-1 |
Contains a node publish an image stream from single image file or avi motion file. |
meta-ros2-jazzy |
| image-publisher |
6.0.11-1 |
Contains a node publish an image stream from single image file or avi motion file. |
meta-ros2-kilted |
| image-rotate |
7.1.3-1 |
<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-ros2-rolling |
| image-rotate |
1.17.0-1 |
<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-noetic |
| image-rotate |
3.0.9-1 |
<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-humble |
| image-rotate |
5.0.11-1 |
<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-jazzy |
| image-rotate |
6.0.11-1 |
<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-kilted |
| image-tools |
0.37.8-1 |
Tools to capture and play back images to and from DDS subscriptions and publications. |
meta-ros2-rolling |
| image-tools |
0.20.9-1 |
Tools to capture and play back images to and from DDS subscriptions and publications. |
meta-ros2-humble |
| image-tools |
0.33.10-1 |
Tools to capture and play back images to and from DDS subscriptions and publications. |
meta-ros2-jazzy |
| image-tools |
0.36.4-1 |
Tools to capture and play back images to and from DDS subscriptions and publications. |
meta-ros2-kilted |
| image-transport |
6.4.7-1 |
image_transport should always be used to subscribe to and publish images. It provides transparent support for transporting images in low-bandwidth compressed formats. Examples (provided by separate plugin packages) include JPEG/PNG compression and Theora streaming video. |
meta-ros2-rolling |
| image-transport |
1.12.1-1 |
image_transport should always be used to subscribe to and publish images. It provides transparent support for transporting images in low-bandwidth compressed formats. Examples (provided by separate plugin packages) include JPEG/PNG compression and Theora streaming video. |
meta-ros1-noetic |
| image-transport |
3.1.12-1 |
image_transport should always be used to subscribe to and publish images. It provides transparent support for transporting images in low-bandwidth compressed formats. Examples (provided by separate plugin packages) include JPEG/PNG compression and Theora streaming video. |
meta-ros2-humble |
| image-transport |
5.1.7-1 |
image_transport should always be used to subscribe to and publish images. It provides transparent support for transporting images in low-bandwidth compressed formats. Examples (provided by separate plugin packages) include JPEG/PNG compression and Theora streaming video. |
meta-ros2-jazzy |
| image-transport |
6.1.3-1 |
image_transport should always be used to subscribe to and publish images. It provides transparent support for transporting images in low-bandwidth compressed formats. Examples (provided by separate plugin packages) include JPEG/PNG compression and Theora streaming video. |
meta-ros2-kilted |
| image-transport-plugins |
6.2.4-1 |
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 |
1.15.0-1 |
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 |
2.5.4-1 |
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-humble |
| image-transport-plugins |
4.0.6-1 |
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-jazzy |
| image-transport-plugins |
5.1.1-1 |
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-kilted |
| image-transport-py |
6.4.7-1 |
Python API for image_transport |
meta-ros2-rolling |
| image-transport-py |
6.1.3-1 |
Python API for image_transport |
meta-ros2-kilted |
| image-view |
7.1.3-1 |
A simple viewer for ROS image topics. Includes a specialized viewer for stereo + disparity images. |
meta-ros2-rolling |
| image-view |
1.17.0-1 |
A simple viewer for ROS image topics. Includes a specialized viewer for stereo + disparity images. |
meta-ros1-noetic |
| image-view |
3.0.9-1 |
A simple viewer for ROS image topics. Includes a specialized viewer for stereo + disparity images. |
meta-ros2-humble |
| image-view |
5.0.11-1 |
A simple viewer for ROS image topics. Includes a specialized viewer for stereo + disparity images. |
meta-ros2-jazzy |
| image-view |
6.0.11-1 |
A simple viewer for ROS image topics. Includes a specialized viewer for stereo + disparity images. |
meta-ros2-kilted |
| image-view2 |
2.2.15-4 |
A simple viewer for ROS image topics with draw-on features |
meta-ros1-noetic |
| imagesift |
1.2.19-1 |
For every image, computes its sift features and send a new message with the image, its intrinsic parameters, and the features. Parameters include: display - shows the image on the local computer |
meta-ros1-noetic |
| imagezero |
0.2.5-1 |
ImageZero is a fast lossless image compression algorithm for RGB color photos. |
meta-ros1-noetic |
| imagezero-image-transport |
0.2.5-1 |
A plugin to image_transport for transparently sending images encoded with ImageZero. |
meta-ros1-noetic |
| imagezero-ros |
0.2.5-1 |
A library that provides convenient methods for manipulating ROS images with ImageZero |
meta-ros1-noetic |
| imath |
3.1.9+gitX |
|
meta-ros-common |
| imlibpurpleservice |
3.0.5+git |
Instant Messaging service |
meta-luneos |
| imu-calib |
0.1.0-2 |
ROS2 package for computing and applying IMU calibration parameters |
meta-ros2-humble |
| imu-complementary-filter |
2.2.2-1 |
Filter which fuses angular velocities, accelerations, and (optionally) magnetic readings from a generic IMU device into a quaternion to represent the orientation of the device wrt the global frame. Based on the algorithm by Roberto G. Valenti etal. described in the paper "Keeping a Good Attitude: A Quaternion-Based Orientation Filter for IMUs and MARGs" available at http://www.mdpi.com/1424-8220/15/8/19302 . |
meta-ros2-rolling |
| imu-complementary-filter |
1.2.7-1 |
Filter which fuses angular velocities, accelerations, and (optionally) magnetic readings from a generic IMU device into a quaternion to represent the orientation of the device wrt the global frame. Based on the algorithm by Roberto G. Valenti etal. described in the paper "Keeping a Good Attitude: A Quaternion-Based Orientation Filter for IMUs and MARGs" available at http://www.mdpi.com/1424-8220/15/8/19302 . |
meta-ros1-noetic |