Abstract: A lidar sensing system for a vehicle includes a sensor module having a laser unit, a sensor unit, and a cover unit. The laser unit includes a housing with reference surfaces machined thereat for positioning laser tubes. The laser unit includes a tension spring that urges the laser tubes against the reference surfaces of the housing. The sensor unit includes a holder with reference surfaces machined thereat for positioning receiver tubes. The sensor unit includes a tension spring that urges the receiver tubes against the reference surfaces of the holder. The holder is attached at the housing and the cover unit is attached at the housing. An output of the sensor module is communicated to a control that, responsive to the output of the sensor module, determines the presence of one or more objects exterior the vehicle and within the field of sensing of the sensor module.

Abstract: A LiDAR system for tracking small flying objects. Multitude of individual LiDAR heads are placed on arcuate frames that intersect to define a dome. Each LiDAR head can be independently rotated with six degrees of freedom. Optical data signals are routed from each LiDAR to a central mirror disposed within the dome and then to a spectrometer for data processing. Upon detection of a possible target by one or more of the LiDAR heads, additional LiDAR heads are rotated to also focus on the possible target, thereby enhancing imaging of the target.

Abstract: A laser rangefinder may include a housing supporting an objective optic, an eyepiece optic, and a view-thru display. The view-thru display may be located along an optical path between the objective optic and the eyepiece optic. The view-thru display may comprise a first transparent sheet and a plurality of electrodes disposed on a first inner surface of the first transparent sheet. The view-thru display may be disposed rearward of the objective optic and the eyepiece optic may be disposed rearward of the view-thru display assembly so that a scene or subject can be viewed through the eyepiece optic and a plurality of display elements selectively displayed by the view-thru display assembly are superimposed on the scene or subject being viewed. Information regarding wind in proximity to the laser rangefinder may be presented on the view-thru display.

Abstract: A pulsed light source illuminates a scene with a virtual array of points. Light reflected by the scene is detected by a small pixel array, allowing generation of a three-dimensional map of the scene. A processing element processing data output by the small pixel array uses a multipath resolution algorithm to resolve individual objects in the scene.

Abstract: A transmitter unit of a lidar device for a scanning system includes at least two radiation sources in the form of semiconductor lasers for generating and emitting electromagnetic beams in the form of a line in a scanning region, the at least two radiation sources being individual emitters directly interconnected mechanically and electrically.

Abstract: An apparatus includes a detector and a light source configured to emit light. The apparatus further includes a disk with a set of prisms and that is configured to rotate, arranged to receive and direct the emitted light, and arranged to receive and direct backscattered light. The apparatus further includes a reflecting apparatus with multiple reflective facets and configured to rotate, arranged to reflect the emitted light, and arranged to reflect the backscattered light. A focusing apparatus is arranged to focus the backscattered light from the disk towards the detector.

Abstract: A Distance Measuring (DM)-system comprising a DM-device comprising a measuring beam unit configured for determining a distance between an object and the DM-device by transmitting a measuring beam, and an Inertial Measurement Unit (IMU) configured for determining an absolute first rotational position of the DM-device with respect to a first axis being parallel to the measuring beam, and an absolute second rotational position of the DM-device with respect to a second axis parallel to the gravity field. The DM-system also includes a computer unit configured for receiving from the DM-device a plurality of measured distance values, an absolute first rotational position of the DM-device at the time of a respective distance measurement, and an absolute second rotational position of the DM-device at the time of a respective distance measurement, and generating a layout by consecutively linking the measured distances based on the plurality of measured distance values.

Abstract: A airborne range finder arranged on an aircraft for surveying a target, the finder comprising an emitter configured for emitting electromagnetic pulses towards the target, a receiver for receiving backscattered pulses, wherein the receiver comprises a projection surface comprising an inner area and an outer area, focusing optics configured for imaging pulses backscattered from a distance equal to or longer than a threshold distance onto the inner area, and pulses backscattered from a distance shorter than said threshold distance onto the inner area and a part of the outer area, a detector configured for detecting and outputting pulses imaged onto the projection surface, and a recorder configured for reading the detector and storing pulses detected only within the inner area as target pulses, storing pulses detected within the outer area as near-field pulses, and tagging each stored pulse with a corresponding pulse reception time, and a control unit.

Abstract: An apparatus includes a detector, a light source configured to emit light, a reflecting apparatus having multiple reflective facets, and a mirror. The reflecting apparatus is configured to rotate around an axis and arranged to reflect the emitted light from the light source and reflect backscattered light. The mirror is arranged to reflect the backscattered light from the reflecting apparatus towards the detector.

Abstract: An optical distance meter configured to carry out a distance measurement in a first measuring mode, in which the distance meter is set for distance measurement on a retroreflective target, and a second measuring mode, in which the distance meter is set for distance measurement on a diffusely scattering target. In this case, a first aperture of the receiving channel is set in the first measuring mode, which is smaller than an aperture set in the second measuring mode.

Abstract: A polygon scanner (10) for detecting objects (24) in a monitored zone (22) is provided having a light transmitter (12); having a light receiver (30); having an evaluation unit (32); and having a rotatable mirror unit (20) for a periodic deflection of the light beam (16) that has a plurality of mirror facets (34) in order thus to scan an angular section multiple times per rotation of the mirror unit (20) by a respective mirror facet (34), wherein at least some of the mirror facets (34) have a different curvature from one another. In this respect, at least one of the mirror facets (34) is configured as a free-form surface whose curvature is adapted to the angle of incidence of the transmitted light beam (16) on the mirror facet (34) that varies during the rotation of the mirror unit (20).

Abstract: A system align point clouds obtained by sensors of a vehicle using kinematic iterative closest point with integrated motions estimates. The system receives lidar scans from a lidar mounted on the vehicle. The system derives point clouds from the lidar scan data. The system iteratively determines velocity parameters that minimize an aggregate measure of distance between corresponding points of the plurality of pairs of points. The system iteratively improves the velocity parameters. The system uses the velocity parameters for various purposes including for building high definition maps used for navigating the vehicle.