Disclosed is a display device for a vehicle interior system. The display device includes a display module having a glass substrate, an organic light emitting diode (OLED) display, and a support member. The glass substrate has a first major surface and a second major surface opposite to the first major surface. The OLED display is disposed on the second major surface of the glass substrate, and the support member includes a first support surface and a second support surface opposite to the first support surface. the OLED display is disposed on the first support surface. The display device also includes a mounting element disposed on the second support surface of the support member. The support member and the mounting element have respective first and second stiffnesses. the first stiffness is at least 100 N/mm, and an effective stiffness of the first and stiffnesses is no more than 270 N/mm.

A vehicle part including a light source capable of emitting a light image, a micro-mirror plate capable of projecting the light image outside the vehicle part in the form of a hologram, a privacy filter located between the light source and the hologram, and a sensor capable of detecting the presence of any object in a projection plane coinciding at least partially with the hologram.

A floating-information display includes a first quarter-wave retarder disposed on a side of an optical plate. A reflective polarizer is disposed between the first quarter-wave retarder and the optical plate. A first display is configured to transmit a first image along a first axis through the first quarter-wave retarder to the reflective polarizer. The reflective polarizer redirects the first image along a second axis through the first quarter-wave retarder toward a viewer. The first image appears to the viewer to be oriented normal to the second axis and at a first location. A second display is configured to transmit a second image to the optical plate. The second image is transferred through the first quarter-wave retarder along the second axis toward the viewer. The second image appears to the viewer to be oriented normal to the second axis and at a second location.

Systems and methods for projecting a multi-faceted image onto a convex polyhedron based on an input image are described. A system can include a controller configured to determine a mapping between pixels within a wide-angle image and a multi-faceted image, and generate the multi-faceted image based on the mapping.

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 method of creating an apparent three-dimensional image of an object includes determining a first position of a user, creating a first two-dimensional image of the object, determining a second position of the user that is different from the first position, creating a second two-dimensional image of the object that is different from the first two-dimensional image, presenting the first two-dimensional image to the user only when the user is disposed in the first position, and presenting the second two-dimensional image to the user only when the user is disposed in the second position to thereby create the apparent three-dimensional image. A display system is also disclosed.

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 novel display system and a moving object are provided. The display system includes a display panel and a display driver. The display panel has a curved shape. The display panel includes a first display region and a second display region on the curved surface. The display driver generates first analog data by a first clock signal and first digital data and generates second analog data by a second clock signal and second digital data. An image can be displayed in accordance with the curved shape of the display panel by transmitting the first analog data to the first display region and transmitting the second analog data to the second display region.

A device for data projection, comprising a holographic element to be arranged by a windshield. An imaging device comprising a first imaging system is arranged at a first angle with respect to the holographic element and configured to illuminate the holographic element at a first illumination angle with first illumination light modulated with first image data. A second imaging system is arranged at a second angle with respect to the holographic element and configured to illuminate the holographic element at a second illumination angle different from the first illumination angle with second illumination light modulated with second image data such that on the holographic element the first illumination light overlaps with the second illumination light. The holographic element comprises a first volume hologram structured to be angle-selective for light under the first illumination angle and to generate a first two-dimensional virtual image at a first fixed distance from the holographic element corresponding to the first image data, and a second volume hologram structured to be angle-selective for light under the second illumination angle and to generate a second two-dimensional virtual image at a second fixed distance from the holographic element different from the first distance corresponding to the second image data, such that the first and second images are viewable separately and simultaneously by a person.

The disclosure relates to providing of a display that can provide content through either a virtual image from a heads-up-display or a transparent display physically adhered to the back surface of the heads-up-display. The aspects disclosure herein also relate to providing a detection of an input, and in response to detection, switching the combined display from a first mode to a second mode.