A vehicle camera includes an image sensor and a variable lens. The variable lens includes a liquid crystal layer that includes liquid crystal molecules having an arrangement that depends on a voltage applied to the liquid crystal layer. The variable lens is configured to, based on the arrangement of the liquid crystal molecules in the liquid crystal layer, alter light that is introduced into the image sensor.

A head-up display includes at least three light sources, each one arranged to emit light with a basic color different from the basic color of the other light sources, a digital micro mirror device including an array of micro mirrors, wherein the light of the light sources is directed onto the digital micro mirror device, at least one combiner for displaying an image, and at least one control unit for multiplexing the light sources so as to sequentially emit light thus creating a field sequential color system and for controlling the digital micro mirror device so as to selectively rotate the micro mirrors between an on state, where the light from the light sources is reflected into an optical path towards the combiner, and an off state, where the light is reflected away from that optical path. A method for operating the head-up display is also disclosed.

A drive support display device supporting a drive of a self-vehicle based on a detection result by an object detector regarding a nearby area of the self-vehicle. The device receives object information from an external source, the object information identifying a nearby object existing in the nearby area of the self-vehicle, determines whether the nearby object is detected by the object detector, and provides a warning indicator when the determination section determines that the nearby object is an undetected nearby object that is not detected by the object detector. As a result, the undetected nearby object, which is already identified as existing somewhere nearby the self-vehicle but is invisible therefrom, may be emphasized in an image provided by the drive support display device.

A vehicle surroundings monitoring apparatus is configured to be provided in an own vehicle and to perform image display related to information on a situation of surroundings of the own vehicle. The own vehicle includes a windshield. The vehicle surroundings monitoring apparatus includes an image generator and an image display. The image generator is configured to generate an image expressing an environment of the surroundings of the own vehicle. The image includes an own vehicle forward image having a view substantially equivalent to a view of a forward region of the own vehicle that is viewable by an occupant of the own vehicle through the windshield at a time of normal driving of the own vehicle. The image display is configured to be disposed on forward side of the occupant of the own vehicle and faces the occupant, and to display the image generated by the image generator.

Provided is a vehicle control device mounted on a vehicle including headlights. The vehicle control device includes an environment recognition unit, an image generation unit, an image display unit, and an illumination range detector. The environment recognition unit acquires surrounding environment formation around the vehicle. The image generation unit generates, on a basis of the surrounding environment information, an environment image that includes forward environment information on environment forward of the own vehicle. The image display unit displays the environment image. The illumination range detector detects an illumination range, in which the illumination range is illuminated by the headlights. The environment image solely includes information acquired inside the illumination range.

A display control device includes an obtainer and a controller. The obtainer obtains a detection accuracy of an object that exists in surroundings of a movable body. When the obtainer obtains a first detection accuracy, the controller controls an image generator so as to generate a first predetermined image that shows a first graphic having a predetermined shape and divided into n regions (n is an integer greater than or equal to 2). When the obtainer obtains a second detection accuracy that is lower than the first detection accuracy, the controller controls the image generator so as to generate a second predetermined image that shows a second graphic having a predetermined shape and undivided or divided into m regions (m is an integer that is greater than or equal to 1 and that is smaller than n).

At least one imaging unit for emitting an image in the form of a beam path and at least one mirror module for deflecting the beam path which is emitted by the imaging unit are included in a head-up display for a motor vehicle. The mirror module includes at least two different mirrors which are movable into the beam path, and a respective curvature of the mirrors is matched to respective vehicle-specific windshield variants. The head-up display may be arranged in the motor vehicle by selecting one of the mirrors whose curvature is matched to the windshield variant, embodied in a vehicle-specific manner, and arranging the selected mirror in a region through which the beam path extends in the case of an activated imaging unit.

The present application discloses a head-up display device which is mounted on a vehicle. The head-up display device includes a projection device which emits image light onto a reflective surface including a first area, and a second area below the first area. The image light includes first image light representing first information including information about an external factor outside the vehicle, and second image light representing second information about the vehicle itself. The projection device emits the first image light onto the first area and the second image light onto the second area.

A vehicle includes a vehicle seating assembly defining a first occupant space. The assembly includes a seat bottom and a seat back operably coupled to the seat bottom. The seat back includes a head rest area and a back panel. A display is positioned on a rear of the seat back. A first camera is positioned within the display and configured to transmit a first video signal. A human machine interface includes a screen configured to display the first video signal from the first camera.

A display system includes a plurality of display screens and a display controller. The plurality of display screens are disposed in front of the driver of the vehicle in a vertical direction in a row such that the distance from the viewpoint position of the driver differs, and present images showing predetermined information to the driver. The display controller is configured to display the images with a lower color temperature on the plurality of display screens, as the distance from the viewpoint position is longer.