A vision system for a vehicle includes a first imager located at a front portion of the vehicle, a second imager located at the rear of the vehicle, a third imager located in a first exterior rearview mirror assembly of the vehicle and a fourth imager located in a second exterior rearview mirror assembly of the vehicle. Responsive to the vehicle being shifted into a reverse gear, (a) video images derived from image data captured by the second imager are displayed on a video display screen and (b) responsive at least in part to processing of captured image data by a common image processor, the driver of the vehicle is alerted to the presence of an object exterior the equipped vehicle. When the vehicle travels forward, the common image processor processes first image data captured by the first imager for at least a lane departure warning system of the vehicle.

A mirror assembly for a vehicle comprises a switchable reflective element that can change between a high reflection state and a low reflection state. The mirror assembly also includes a controller communicating with the switchable reflective element, the controller being able to change the switchable reflective element between a high reflection state and a low reflection state. The mirror assembly further includes a housing configured for attachment to the vehicle and housing at least the switchable reflective element.

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 mirror reflective element sub-assembly suitable for use for a vehicular exterior rearview mirror assembly includes a mirror reflective element, a signal indication module and a mirror back plate attached at the mirror reflective element. The signal indication module attaches to the mirror reflective element via an aperture of the back plate and has a light source that is activatable to emit light. The signal indication module includes a housing that substantially encases the light source. The signal indication module includes an inner surface at an angle relative to the mirror reflective element. The signal indication module includes a baffle disposed at the inner surface and at least partially in front of the light source, the baffle partially but not fully occluding light emitted by the light source to reduce a bright spot at the reflective element when viewed when the light source is activated.

A method for operating a motor vehicle with at least one exterior camera includes detecting whether the motor vehicle is put into operation before a driver gets into the motor vehicle, determining whether there is any contamination of the at least one exterior camera, in particular of a lens and/or a cover of the exterior camera, and outputting at least one signal in the event of certain contamination and detected start-up. A motor vehicle includes a control or regulating device designed to carry out the method.

A vehicle periphery monitoring device includes a plurality of sensors including a rear camera, a rear right-side camera, and a rear left-side camera, a display unit that is provided inside a vehicle cabin, memory, and a processor that is coupled to the memory. The processor is configured so as to acquire a rear image that includes a first image of a vehicle rear side acquired by the rear camera, a second image of a vehicle rear right-side acquired by the rear right-side camera, and a third image of a vehicle rear left-side acquired by the rear left-side camera, acquire from the plurality of sensors relative positions of a target that is present in areas including the vehicle rear side, the vehicle rear right-side, and the vehicle rear left-side relative to a host vehicle, determine whether or not the acquired relative positions of the target are mutually consistent with each other in the plurality of sensors, display a single composite image that is created by combining the first image, the second image, and the third image at the display unit in a case in which it is determined that the relative positions of the target are mutually consistent with each other, and display the first image, the second image, and the third image individually and adjacently to each other on the display unit in a case in which it is determined that the relative positions of the target are not mutually consistent with each other.

A motor vehicle includes a rearview mirror display system with a visible surface and having a mirror mode and a display mode. The visible surface functions as a mirror in the mirror mode. The visible surface displays an electronically produced image in the display mode. An electronic processor is communicatively coupled to the rearview mirror display system. The electronic processor detects that the display mode is not operating properly, and, in response to the detecting, automatically switches the rearview mirror display system from the display mode to the mirror mode.

A movable carrier auxiliary system includes at least two optical image capturing systems respectively disposed on a left portion and a right portion of a movable carrier. Each optical image capturing system includes an image capturing module, an operation module, at least one warning module, and at least one displaying device, and has at least one lens group including at least two lenses having refractive power. The image capturing module captures and produces an environmental image surrounding the movable carrier. The operation module electrically connected to the image capturing module detects at least one moving object in the environmental image to generate a detecting signal. The warning module electrically connected to the operation module receives the detecting signal, and generates a warning signal when determines that the moving object approach to the movable carrier. The displaying device is electrically connected to the warning module to display the warning signal.

A display device may comprise a transmittance control structure having a variable transmittance and a mirror type display panel disposed on a rear surface of the transmittance control structure. The mirror type display panel may comprise a substrate, a display member disposed on the substrate, the display member including a light emission region, a first transmission region, and a peripheral region surrounding the light emission region and the first transmission region, and a reflective member facing the substrate with respect to the display member, the reflective member including an opening region corresponding to the light emission region, a second transmission region corresponding to the first transmission region, and a reflective region surrounding the opening region and the second transmission region.

An overhead console includes a console housing, an illumination board, a vehicle interior checking mirror, a mirror surface light source mounted on the illumination board together with the illumination light source and configured to emit light toward the mirror surface of the vehicle interior checking mirror in the mirror surface visible position, and a see-through display plate that is a display plate capable of transparently displaying a symbol indicating predetermined information, the see-through display plate being provided in the console housing at a location between the mirror surface light source and the mirror surface so as not to hinder the passenger from visually recognizing the mirror surface and so as to face a partial region of the mirror surface, and the see-through display plate being configured to allow light from the mirror surface light source to transmit therethrough to display the symbol on the partial region of the mirror surface.