A vehicular exterior breakaway rearview mirror assembly includes a skull-cap mirror shell and a reflective element. With the mirror assembly mounted at an exterior side of a vehicle, the skull-cap mirror shell has an inboard wall that faces toward the exterior side of the vehicle. A blind spot indicator is disposed at an aperture established at the inboard wall of the skull-cap mirror shell. An illumination source of the blind spot indicator is activated to illuminate the blind spot indicator responsive to an electronic blind spot monitoring system of the vehicle detecting another vehicle that is approaching or overtaking the equipped vehicle. Illumination of the blind spot indicator by activation of the illumination source is readily viewable by the driver of the equipped vehicle and is not readily viewable by a driver of the detected other vehicle.

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 vehicular exterior rearview mirror assembly includes a mounting structure, a mirror reflective element, a mirror back plate, a heater element, and a blind zone indication module. The heater pad is disposed between the mirror back plate and the mirror reflective element. The blind zone indication module is located at an aperture formed through the mirror back plate. The blind zone indication module includes a housing that houses a circuit element and a light source. The circuit element includes electrically conductive terminals that are in electrical connection with circuitry of the circuit element and that are disposed at a connector portion of the housing that is configured to connect to a wire harness to electrically power circuitry of the circuit element when the vehicular exterior rearview mirror assembly is mounted and used at a vehicle.

A device for displaying lateral rear images of a vehicle using a room mirror for a vehicle, includes: a smart room mirror 10 equipped with a camera sensor 11 for recognizing a driver's gesture and a motion sensor 12 for recognizing a driver's 3D gesture; camera modules 310, 410 for capturing vehicle lateral rear images, installed in left and right side-view mirrors 30, 40 of a vehicle 20; and a central processing device 60 for controlling to store, compare and analyze image information from the camera modules 310, 410 installed in the left and right side-view mirrors 30, 40, respectively, and image information from the camera sensor 11 and the motion sensor 12 of the smart room mirror 10, the central processing device 60 controlling to access a black box 50 and a communication module 51 and receive images stored in the black box 50.

A vehicular exterior rearview mirror assembly includes a mirror reflective element sub-assembly having a mirror reflective element, a mirror reflector, a mirror back plate, and indicator element. The indicator element includes a housing and a light source. The indicator element is associated with a blind spot detection system of the vehicle and includes a diffuser that diffuses light emitted by the light source. An icon is established through a metallic reflector coating disposed at the glass substrate. The icon includes a light-transmitting aperture. When the vehicular exterior rearview mirror assembly is attached at the vehicle, the icon is at an upper quadrant of the mirror reflective element. When the vehicular exterior rearview mirror assembly is attached at the vehicle and when the light source is activated, the icon is illuminated and is viewable by the driver of the vehicle.

A vehicular vision system includes a camera having a field of view interior of a vehicle equipped with the vehicular vision system, a plurality of infrared light emitters operable to illuminate a region at least partially within the field of view of the camera, and an electronic control unit having an image processor that processes image data captured by the camera. The camera captures frames of image data at a first rate, and infrared light emitters of the plurality of infrared light emitters are pulsed at a second rate. The first rate is different than the second rate. For a driving assist function of the vehicle, capture of frames of image data by the camera at the first rate is synchronized with pulsing of the infrared light emitters of the plurality of infrared light emitters at the second rate.

A vehicular control system includes a forward viewing camera disposed at an in-cabin side of a windshield of a vehicle and viewing forward of the vehicle. Road curvature of a road along which the vehicle is traveling is determined responsive at least in part to processing of image data captured by the camera. Responsive at least in part to processing of captured image data, speed of the vehicle is controlled by an adaptive cruise control system of the vehicle. Upon approach of the vehicle to a curve in the road along which the vehicle is traveling, speed of the vehicle is reduced by the adaptive cruise control system to a reduced speed for traveling around the curve in the road. Speed of the vehicle is increased by the adaptive cruise control system when the vehicle is traveling along a straighter section of road after the curve in the road.

A rearview mirror with an RGB indicator lamp is provided, and belongs to the technical field of vehicle rearview mirrors. The rearview mirror includes a mirror shell and a mirror frame, and further includes a light module. The light module is installed inside the mirror shell, and a light-emitting panel of the light module is installed on the mirror frame. The light module is compact in structure, small in size and convenient to install on the rearview mirror. Meanwhile, the light-emitting panel is arranged on the mirror frame and integrated with the mirror frame, and the overall color is coordinated and unified.

A vehicle side rear view mirror having means to display information is used to communicate with other individuals outside of the vehicle. The side rear view mirror assembly includes a base to connect it to the vehicle, a mirror case fixed to the base, at least one light source to display forward through a lens an emoticon or other symbol, and at least one controller to turn the assembly on. The assembly may also include a voice recording or other sound to communicate with other individuals outside of the vehicle. The controller, which is located remotely, could be pushed once or twice to turn on the light source. The light source could be used as a marker light. Alternatively, the controller could be an electrical interrupter controller which would cause the light source to flash so that the light source could be used as a turn signal or hazard lamp. Alternatively, the controller could be voice controlled. Alternatively, the controller could be gesture controlled.

The side rear view mirror assembly may include a matrix of light emitting diodes, which could be color light emitting diodes, to display forward an emoticon or other symbol, a controller, and at least one controller to turn the assembly on and select what emoticon is shown. This assembly may also include a voice recording or other sound to communicate with other individuals outside of the vehicle, or as a turn signal, a hazard light, or a marker light. The controller, which is located remotely, could be pushed once or twice to turn on the light emitting diode array. Alternatively, the controller could be voice controlled. Alternatively, the controller could be gesture controlled.

An exterior rearview device for an automotive vehicle includes a cover body with a cover body opening where the cover covers a front part of at least one reflective means, display or camera accommodated in the cover body. The exterior rearview device also contains a light module having a base body, a lens attachable to the base body and a selected functional device selected from at least two different functional devices each of which is adapted to achieve a specific light function. The base body is attachable to the cover body such that, in an attached state, the lens is arranged in the cover body opening, and the selected functional device is attachable to the base body such that, in the attached state, light from the light module passes through the lens to fulfil the specific light function of the selected functional device.