A hub that receives sensor data streams and then distributes the data streams to the various systems that use the sensor data. A demultiplexer (demux) receives the streams, filters out undesired streams and provides desired streams to the proper multiplexer (mux) or muxes of a series of muxes. Each mux combines received streams and provides an output stream to a respective formatter or output block. The formatter or output block is configured based on the destination of the mux output stream, such as an image signal processor, a processor, memory or external transmission. The output block reformats the received stream to a format appropriate for the recipient and then provides the reformatted stream to that recipient.

An autonomous vehicle having a LIDAR system that scans a field of view is described herein. With more specificity, a computing system of the autonomous vehicle defines a region of interest in the field of view for a scan of the field of view by the LIDAR system. The region of interest is a portion of the field of view. Based on the region of interest, the computing system transmits a control signal to the LIDAR system that causes the LIDAR system to emit first light pulses with a first intensity within the region of interest during the scan and second light pulses with a second intensity outside the region of interest during the scan. The first intensity is different from the second intensity to provide different ranges for distance measurements inside and outside the region of interest.

An autonomous vehicle having a LIDAR system that scans a field of view is described herein. With more specificity, a computing system of the autonomous vehicle defines a region of interest in the field of view for a scan of the field of view by the LIDAR system. The region of interest is a portion of the field of view. Based on the region of interest, the computing system transmits a control signal to the LIDAR system that causes the LIDAR system to emit first light pulses with a first intensity within the region of interest during the scan and second light pulses with a second intensity outside the region of interest during the scan. The first intensity is different from the second intensity to provide different ranges for distance measurements inside and outside the region of interest.

A method of controlling augmented reality (AR) mobility according to embodiments may include generating, by a camera, image data by photographing one or more users, extracting information about the one or more users from the image data, calculating a reference point for projection of an AR object based on the location information about the users, and displaying the AR object on a display based on the calculated reference point. An apparatus for controlling AR mobility according to embodiments may include a camera configured to generate image data by photographing one or more users, a controller configured to extract information about the one or more users from the image data, a calibrator configured to calculate a reference point for projection of an AR object based on the location information about the users, and a display configured to display the AR object on a display based on the calculated reference point.

A surround view system for a vehicle, comprising a camera positioned in or on the vehicle to capture the vehicle's surroundings, an evaluation unit processing images captured by the camera and a display displaying a top-view image generated by the evaluation unit. The evaluation unit obtains the top-view image by calculating a projection of the captured images onto a virtual projection surface and by calculating a top-view of the projection on the virtual projection surface. The virtual projection surface comprises a flat bottom part and a rising part adjacent to the flat bottom part, wherein, in an area comprising the rising part at one side of the vehicle over a length of the vehicle, a curvature of the virtual projection surface is zero in a longitudinal direction of the vehicle.

A method for automatic generation of calibration parameters for a surround view (SV) camera system is provided that includes capturing a video stream from each camera comprised in the SV camera system, wherein each video stream captures two calibration charts in a field of view of the camera generating the video stream; displaying the video streams in a calibration screen on a display device coupled to the SV camera system, wherein a bounding box is overlaid on each calibration chart, detecting feature points of the calibration charts, displaying the video streams in the calibration screen with the bounding box overlaid on each calibration chart and detected features points overlaid on respective calibration charts, computing calibration parameters based on the feature points and platform dependent parameters comprising data regarding size and placement of the calibration charts, and storing the calibration parameters in the SV camera system.

A motor vehicle, having a plurality of image recording devices arranged across the entire vehicle for recording images of the vehicle environment, includes a control device for generating an image representation showing the 360 environment around the motor vehicle on the basis of the images. The motor vehicle further includes a display device for displaying the image representation. The control device is designed to generate an additional partial image representation showing the area below the motor vehicle on the basis of images recorded, and to integrate the partial image representation into the displayed image representation for outputting an overall image representation. At least one sensor device is provided which detects the area below the motor vehicle and communicates with the control device. The overall image representation can be modifiable at least in the area of the partial image representation on the basis of the sensor information.

A system includes a camera having a field of view, a cleaning apparatus positioned to clean the camera, and a computer communicatively coupled to the camera and the cleaning apparatus. The computer is programmed to detect an obstruction on the camera based on sensing a trajectory of an external light source relative to the field of view in data from the camera, and upon detecting the obstruction, activate the cleaning apparatus.

Methods and systems are provided for a dual function imaging device. In one example, a method may comprise imaging exhaust gas outside of a reverse engine condition via the imaging device. The imaging device may image a surrounding area during the reverse engine condition.

The present disclosure relates to a method of generating a surround view of a vehicle platoon and a device thereof. A surround view generating device for a vehicle in the vehicle platoon acquires a local surround view of the vehicle and at least one of a truncated local surround view associated with one or more preceding vehicles and a truncated local surround view associated with one or more following vehicles in the vehicle platoon. Further, the surround view generation device generates a surround view of the vehicle platoon using the local surround view of the vehicle, the truncated local surround view associated with the one or more preceding vehicles, and the truncated local surround view associated with the one or more following vehicles. Finally, the surround view generating device navigates the vehicle in the vehicle platoon based on the surround view of the vehicle platoon.