Packages that infer the presence of obstacles from sensor inputs.
A ROS 2 node that subscribes to LaserScan
messages and publishes obstacles to /rmf_obstacles
.
The node is implemented as anrclcpp::lifecycle_node
node where upon activation, it calibrates the surroundings based on the range values in the initial few LaserScan
messages.
This essentially becomes the "obstacle-free" configuration.
Subsequently, any changes to the surroundings is detected as an obstacle.
To run
ros2 run rmf_obstacle_detector_laserscan laserscan_detector
Note: The node can also be loaded into a ROS 2 component container as a plugin (
LaserscanDetector
)
The node accepts the following parameters
Parameter Name | Description | Default Value |
---|---|---|
scan_topic_name |
The topic over which LaserScan messages are published. It is strongly recommended to filter the scan to remove out-of-range rays before passing it to this node. |
/lidar/scan |
range_threshold |
For each ray, if the difference in range measurement between the latest LaserScan and the calibrated one is grater than this value, a new obstacle is assumed. |
1.0 meter |
min_obstacle_size |
The minimum perceived size of an object for it to be considered an obstacle. | 0.75 meter |
level_name |
The level(floor) name on which the scanner exists. | L1 |
calibration_sample_count |
The number of initial LaserScan messages to use for calibrating the "obstacle-free" configuration. |
10 |
A ROS 2 node that detects humans via on-chip-inference on OAK-D
cameras and publishes the detections over /rmf_obstacles
as rmf_obstacle_msgs::Obstacles
message.
The node can be run either as a component within a ROS 2 container or as a standalone node.
The component plugin is rmf_human_detector_oakd::HumanDetector
and can be loaded into a ComponentManager
via ros2 component load <COMPONENT_MANAGER> rmf_human_detector_oakd::HumanDetector
.
To launch as a standalone node,
ros2 launch rmf_human_detector_oakd human_detection.launch.xml blob_path:=<PATH_TO_MOBILENET-SSD_BLOB>
THe node has several configurable parameters documented in the launch file.
The most important of which is blob_path
as it holds the absolute path to the NN model for inference. See depthai
documentation for more information on how the various pre-trained models can be obtained.
It is recommended to use the blobconverter tool to obtain the mobilenet-ssd_openvino_2021.4_6shave.blob
blob for inference.
To visualize the detection frames, set debug:=True
. Note: Frames will only be visualized when a human is actively detected.
For more information on setup and troubleshooting see here
A ROS 2 node that subscribes to sensor_msgs::Image
messages published by a monocular camera and runs Yolo-V4
to detect the presence of humans. The relative pose of the humans with respect to the camera frame is estimated based on heuristics that can be configured through ROS 2 params.
The use case for this node would be to detect crowds from existing CCTV cameras or vision sensors in the facility.
To run:
ros2 launch rmf_human_detector human_detector_launch.py