An example computing device includes a time of flight (ToF) sensor to generate frames of sensor data. The computing device includes a processor to: identify an object appearing in the frames; track a centroid of the object frame-by-frame; and determine whether a user is present within operating range of the computing device based on the tracking.

A surveying system comprises a laser scanner for scanning a distance measuring light and for acquiring point cloud data and a target instrument having a target for reflecting the distance measuring light, wherein the target is a sphere having a known diameter, the laser scanner comprises a distance measuring module for projecting the distance measuring light, for receiving a reflected distance measuring light and for performing a distance measurement, an optical axis deflector which enables to two-dimensionally deflect the distance measuring light, and an arithmetic control module for controlling the optical axis deflector, and wherein the arithmetic control module is configured to perform a circular scan on a surface of the target by the optical axis deflector, to obtain a center of the target based on the point cloud data acquired by the circular scan and the diameter, and to measure a distance of the center of the target.

A DE energy weapon and tracking system includes a passive millimeter wave (PmmW) imaging receiver on a common gimbaled telescope to sense natural electromagnetic radiation from a mmW scene. The PmmW imaging receiver operates in a portion of the electromagnetic spectrum distinct from the IR bands associated with thermal blooming or the HEL laser. In the case of a HPM source, the reflected energy is either in a different RF band and/or of diminished amplitude such as to not interfere with operation of the PmmW imaging receiver. Although lower resolution than traditional optical imaging, PmmW imaging provides a viable alternative for target tracking when the DE weapon is actively prosecuting the target and provides additional tracking information when the DE weapon is not engaged.

A DE energy weapon and tracking system includes a passive millimeter wave (PmmW) imaging receiver on a common gimbaled telescope to sense natural electromagnetic radiation from a mmW scene. The PmmW imaging receiver operates in a portion of the electromagnetic spectrum distinct from the IR bands associated with thermal blooming or the HEL laser. In the case of a HPM source, the reflected energy is either in a different RF band and/or of diminished amplitude such as to not interfere with operation of the PmmW imaging receiver. Although lower resolution than traditional optical imaging, PmmW imaging provides a viable alternative for target tracking when the DE weapon is actively prosecuting the target and provides additional tracking information when the DE weapon is not engaged.

An aspect of the present disclosure relates to a system implemented in a host vehicle, comprising: a radar based detection unit, comprising one or more radar sensors, for detecting one or more targets around the host vehicle; a vision based detection unit, comprising one or more image sensors, for detecting one or more targets in the field of view of the host vehicle; and a processing unit to: receive information corresponding to detected one or more targets from each of the radar based detection unit and the vision based detection unit; match each of the one or more targets detected by the radar based detection unit with one or more targets detected by vision based detection unit to identify a target as a matched target; categorize the matched target as a locked target; and track the locked target using information received from the radar based detection unit.

A surveying instrument for executing a relocation functionality, which determines first coordinates of a stationary target point associated with the start signal, in response to a start signal, a first actuator and a second actuator are controlled such that the stationary target point remains within a detection area of a tracking unit of the surveying instrument, determines second coordinates of the stationary target point, receives an end signal, wherein the second coordinates of the stationary target point are associated with the end signal, and based at least in part on the first and second coordinates of the stationary target point, and determines a relative pose of the surveying instrument with respect to a first setup location and a second setup location, wherein the first setup location is associated with the first coordinates and the second setup location is associated with the second coordinate.

In order to continuously acquire positional information of a moving body without losing sight of a target provided to the moving body, a moving body control system 1 a includes a moving body 100a with a target 100a, a positional information transmission apparatus 200 transmitting positional information of the target 100a on the basis of tracking the target 100a, a collimation possibility determining unit 109 determining, on the basis of an inclination of the moving body 100 predicted depending on a movement control instruction for moving the moving body 100, whether or not an incident angle at which a straight line connecting the positional information transmission apparatus 200 and the target 100a enters the target 100a falls within a prescribed range, and a control instruction changing unit 111 changing the movement control instruction based on the result of the determination.

A distance measurement apparatus includes a light emitting apparatus capable of emitting first light and second light having a smaller spread than the first light, and changing an emission direction of the second light, a light receiving apparatus, and a processing circuit. The processing circuit performs a process including causing the light receiving apparatus to detect reflected light that occurs due to the first light and reflected light that occurs due to the second light, and generate therefrom first distance data and second distance data, when an object is present outside a first target area included in an area illuminated by the first light, causing the light emitting apparatus to track the object by the second light; and when the object enters the inside of the first target area from the outside of the first target area, causing the light emitting apparatus to stop the tracking by the second light.

A distance measurement apparatus includes a light emitting apparatus capable of emitting first light and second light having a smaller spread than the first light, and changing an emission direction of the second light, a light receiving apparatus, and a processing circuit. The processing circuit performs a process including causing the light receiving apparatus to detect reflected light that occurs due to the first light and reflected light that occurs due to the second light, and generate therefrom first distance data and second distance data, when an object is present outside a first target area included in an area illuminated by the first light, causing the light emitting apparatus to track the object by the second light; and when the object enters the inside of the first target area from the outside of the first target area, causing the light emitting apparatus to stop the tracking by the second light.

A method of tracking an object using a LiDAR sensor includes: acquiring a point cloud using each of LiDAR sensors and clustering the point cloud. The clustering includes generating a three-dimensional (3D) grid map using the point cloud acquired by each of the LiDAR sensors; labeling voxels present in the 3D grid map with one cluster using direction points of the voxels; and checking whether it is necessary to label the voxels with mutually different clusters.