A motor vehicle includes a left side view camera attached to the left lateral side of the body and having a field of view in a rearward direction. A right side view camera is attached to the right lateral side of the body and has a field of view in a rearward direction. There is a right back up camera and a left back up camera. An optics module receives resulting video signals and produces light fields such that the light fields are reflected off of windows of the motor vehicle and are then visible to a driver of the motor vehicle as virtual images.

The present invention relates to a vehicle display device comprising: a display unit comprising a transparent flexible display disposed in a state of being rolled around a certain axis; a driving unit for adjusting the length of a region, of the transparent flexible display, exposed inside the vehicle; and a processor for controlling the driving unit and controlling the display of a picture on the transparent flexible display.

Disclosed is a driving environment information display method including acquiring environment information, selecting a first seed image corresponding to a curvature of a road on which driving is performed based on the acquired environment information, from among a plurality of lane surface seed images having different curvatures, disposing the selected first seed image at a display origin corresponding to a vehicle origin, primarily distorting the first seed image in a direction toward a target lane surface that becomes a display target based on a host vehicle in response to a first lateral distance of an adjacent lane division line located in the direction toward the target lane surface, secondarily distorting the image in the direction toward the target lane surface in response to a half of the lane width of a driving lane of the host vehicle, and outputting the secondarily distorted image through a display unit.

An object image extraction unit (110) extracts, from a photographed image of ahead of a vehicle, an extracted object image matching an extraction condition among a plurality of object images. A display allocation area specifying unit (130) specifies in the photographed image, an area that does not overlap any extracted object image and that is in contact with any extracted object image, as a display allocation area of guidance information, and identifies an adjacent extracted object image that is in contact with the display allocation area and a tangent of the adjacent extracted object image to the display allocation area. An object space coordinate calculation unit (140) calculates a three-dimensional space coordinate of an object of the adjacent extracted object image, as an object space coordinate. A tangent space coordinate calculation unit (160) calculates, based on the object space coordinate, a three-dimensional space coordinate of the tangent on the assumption that the tangent exists in a three-dimensional space, as the tangent space coordinate. A display area determination unit (170) determines a display area of the guidance information on a windshield, based on the tangent space coordinate and three-dimensional space coordinates of the eye position of a driver and the position of the windshield.

An image processing device for a vehicle includes: an acquisition unit acquiring a captured image of a periphery of a vehicle, which is captured by an imaging unit provided in the vehicle; a bird's eye view image generating unit generating a bird's eye view image in which the captured image is projected to a 3D virtual projection plane provided at a side opposite to the vehicle with reference to a ground and separated from the ground with distance from the vehicle; a guide line generating unit generating a guide line indicating a predicted course of the vehicle; a conversion unit converting the guide line into a virtual guide line indicating the predicted course on the virtual projection plane; and a superimposing unit superimposing the virtual guide line on the bird's eye view image.

A display system for a vehicle includes an interior camera disposed in an interior cabin of a vehicle and having a field of view interior of the vehicle that encompasses an area at or near a user input for an accessory, with the user input being accessible by a driver of the vehicle when the driver is normally operating the vehicle. A display device is viewable by the driver when the driver is normally operating the vehicle. The display device is operable to display images derived from image data captured by said interior camera. The display device displays images depicting the driver's hand as the driver's hand approaches the user input for the accessory for actuating the user input to adjust or control the accessory.

According to the invention, provided are a windshield glass including: a projected image display portion on which a projected image is displayed with projected light; and a second glass plate, an intermediate layer, and a first glass plate provided in this order from an incidence side of the projected light, in which the intermediate layer has a wedge-shaped cross section, the projected image display portion at least includes a half-mirror film, and the half-mirror film includes a cholesteric liquid crystal layer, and a head-up display system including the windshield glass. According to the windshield glass of the invention, it is possible to perform a display of a projected image having high brightness, in which generation of a double image is reduced.

A method that simulates effects of displaying assets using a graphical processing unit (GPU) is provided. The method includes extracting preprocessed assets, the assets having been preprocessed offline to provide simulated GPU graphical effects, isolating dynamic assets from static assets from the preprocessed assets, calculating a bounding-box for each of the dynamic assets, alpha-blending the static assets, alpha-blending the dynamic assets, and rendering the static assets and the dynamic assets to separate display layers at different frequencies.

A method for displaying a pointer in an instrument panel is described. The method comprises retrieving a current instrument status of an instrument of the instrument panel that is to be displayed, determining a pointer form on the basis of the current instrument status, retrieving of the determined pointer form from a texture atlas, and rendering the pointer in the instrument panel with the retrieved pointer form. There is further described a device for displaying an instrument panel, which device comprises a display module configured to display at least one instrument panel having at least one pointer instrument, and a controller configured to carry out the method using the display module. A vehicle having such a device is also disclosed.

A method of controlling a VR device, in particular VR goggles, of a user in a vehicle interior of a vehicle via a communication link, includes vehicle data being received and evaluated, or receiving evaluated vehicle data via the communication link. At least one traffic event may be classified based on the evaluated vehicle data, to generate control commands for controlling the VR device, by way of which the user of the VR device may be alerted to a response of the vehicle to the traffic event, which may be unpredictable to the user. The examples further relate to a vehicle arrangement.