A vehicular driver monitoring system includes an interior rearview mirror assembly having a driver monitoring camera and first and second near-infrared light emitting elements accommodated by a mirror head. The light emitting elements are oriented at the mirror head so that (i) a beam of light emitted by the first light emitting element would be directed toward a driver's region of a left hand drive vehicle if the mirror assembly were installed in the LHD vehicle, and (ii) a beam of light emitted by the second light emitting element would be directed toward a driver's region of a right hand drive vehicle if the mirror assembly were installed in the RHD vehicle. The system enables and/or operates the first or second light emitting element for a driver monitoring function responsive to indication that the mirror assembly is installed or will be installed in a LHD vehicle or a RHD vehicle.

A rearview device for a motor vehicle includes a camera arrangement for capturing a rearward traffic situation and a motor vehicle includes such a rearview device and a method for operating such a rearview device with an output unit which is partially reflective at least in regions, in particular a screen on which the rearward traffic situation captured by the camera arrangement is displayed as a camera image or this is visibly displayed by means of a conventional mirror image in the absence of a camera image and having a control unit for determining a degree of impairment of the camera image, the control unit, when a predetermined degree of impairment of the camera image is exceeded.

A sensor assembly for autonomous vehicles includes a side mirror assembly configured to mount to a vehicle. The side mirror assembly includes a first camera having a field of view in a direction opposite a direction of forward travel of the vehicle; a second camera having a field of view in the direction of forward travel of the vehicle; and a third camera having a field of view in a direction substantially perpendicular to the direction of forward travel of the vehicle. The first camera, the second camera, and the third camera are oriented to provide, in combination with a fourth camera configured to be mounted on a roof of the vehicle, an uninterrupted camera field of view from the direction of forward travel of the vehicle to a direction opposite the direction of forward travel of the vehicle.

A process for identifying a road feature in an image includes receiving an image at a controller, identifying a region of interest within the image and converting the region of interest from red-green-blue (RGB) to a single color using the controller. A set edges is detected within the region of interest, and at least one line within the set of edges is identified using the controller. The at least one line is compared with a set of known and expected road marking features, and the set of at least one first line in the at least one line is identified as corresponding to a road feature in response to the at least the first line matching the set of known and expected road marking features.

A method for the reliable and error-robust analysis of visually captured vehicle surroundings is provided. A deviation of a camera orientation caused by a force impacting an exterior mirror carrying the camera can be compensated fully automatically. As a result, the method can be used during active travels in the field and creates more safety, in particular for autonomous driving.

Aspects of the present invention relate to an image correction system (300) for mitigating image flicker from strobed lighting systems. The image correction system (300) comprises one or more controllers (120) comprising input means (122), processing means (121) and output means (122). The input means (122) is configured to receive, from a first imaging apparatus (111) comprising a first pixel array configured to operate with at least a first exposure time, first image data (141) indicative of an environment. The input means (122) are configured to receive, from a second imaging apparatus (112) comprising a second pixel array configured to operate with at least a second exposure time different to the first exposure time, second image data (142) indicative of at least a portion of the environment. The processing means (121) are configured to identify strobed lighting regions of the first image data (141) and strobed lighting regions of the second image data (142); and to determine corrected image data for mitigating image flicker of the strobed lighting regions of the first image data (141) in dependence on a correspondence between the strobed lighting regions of the first image data (141) and the strobed lighting regions of the second image data (142). The output means (122) is configured to output a signal indicative of the corrected image data.

A digital side mirror system comprises imaging devices disposed on both sides of a vehicle, a display device including a screen for outputting images captured by the imaging device, and a control device. The control device receives a pattern board image, generates calibration information that includes at least one of a distance between a reference line and a center of the pattern board image or an angle of the pattern board image with respect to the reference line, and transmits a calibration image that includes the calibration information therein to the display device.

Drive for an adjusting instrument, comprising a single motor, in particular an electric motor, and a driving shaft coupled therewith. The driving shaft cooperates via a transmission selectively with a first and a second driving path respectively. The drive comprises furthermore an operating mechanism with which the transmission is switchable between the first and the second driving path. The operating mechanism is energized by the motor via the driving shaft and is configured, upon successive energization of the motor from rest of the drive, to select alternately the first and the second driving path as initial driving path.

A vehicle mirror system for a vehicle coupled to a trailer is provided. The vehicle mirror system includes first and second mirror assemblies configured to be located on first and second sides of the vehicle, a trailer angle sensor for sensing a hitch angle between the trailer and the vehicle, and a controller for controlling actuation of the first mirror assembly to control a first viewing window of the first mirror assembly for a driver of the vehicle, wherein the first mirror assembly is adjusted to redirect the viewing window to track a feature on the trailer as the trailer articulates relative to the vehicle based on the hitch angle. The second mirror assembly may be controlled to move inwards and downwards.

A sideview mirror assembly for a vehicle can comprise a body including a sideview mirror housing. The sideview mirror assembly can include a camera located in the body about the sideview mirror housing. The camera can have a field-of-view including an above-horizontal region directed rearward toward an overhead target position past the sideview mirror housing. The camera can be mounted for movement relative to the body between a normal position, in which the sideview mirror housing intersects the camera and the overhead target position in the above-horizontal region, and an extended position, in which the sideview mirror housing does not intersect the camera and the overhead target position in the above-horizontal region. Movement of the camera from the normal position to the extended position can unblock camera visibility of the overhead target position by the sideview mirror housing.