A display device of the disclosure is a display device to be mounted on a vehicle, and includes a display panel, a first input unit, a second input unit, a third input unit, and a controller. The first input unit is configured so as to acquire an engine rotation speed. The second input unit is configured so as to acquire a vehicle speed. The third input unit is configured so as to acquire a shift position of a transmission of a vehicle. The controller is configured so that a first image representing the engine rotation speed and one or more second images representing the vehicle speed are combined and a combined image is displayed on the display panel. The controller is configured so that switching of the second images is carried out based on the shift position.

Embodiments of this disclosure pertain to a vehicle interior system comprising a base having a base surface; and a glass article coupled to the surface, wherein the glass article comprises a first portion comprising a first elastically deformed surface forming a first concave shape with a first radius of curvature from about 20 mm to about 2000 mm, and a second elastically deformed surface directly opposite the first elastically deformed surface that forms a second convex shape, wherein the second elastically deformed surface has a surface compressive stress that is less than a compressive stress at the first elastically deformed surface, and a second portion adjacent the first portion, wherein the second portion is substantially planar portion or curved.

A head-up display includes a display device and an optical system. The display device includes a display panel, an input unit, a memory, and a controller. The display panel is configured to display an image. The input unit is configured to receive calibration information indicating a position of a calibration object and first position information indicating positions of user's eyes based on an image capturing device. The memory is configured to store the calibration information. The optical system is configured to allow a user to visually recognize a virtual image plane, which is a virtual image of the image displayed on the display panel, by reflecting image light emitted corresponding to the image toward the user's eyes. The controller is configured to convert the first position information into second position information indicating the positions of the eyes based on the virtual image plane by using the calibration information.

A radio communication head-up display system includes a radio communication device including an imaging element, a first controller, and a first communication module, and a head-up display including a display panel, an optical element, an optical system, and a second controller. The imaging element generates a captured image. The first controller estimates eye-positions of eyes of a user based on the captured image. The first communication module transmits positional information indicating eye-positions of the eyes of the user. The display panel displays a parallax image. The optical element defines a propagation direction of image light. The optical system projects the image light whose propagation direction is defined by the optical element, toward a direction of the eyes of the user. The second communication module receives the positional information indicating the eye-positions. The second controller controls the parallax image displayed on the display panel based on the positional information received.

A user interface for a vehicle is adapted to present visible information capture user input. The user interface includes an optical faceplate having a flat contact surface, a three-dimensional display surface, and an optic light guide material provided between the contact surface and the three-dimensional display surface. A two-dimensional display and the contact surface are arrangeable so that light emitted from the display is receivable by the contact surface. The faceplate is movably arrangeable at the two-dimensional display, and the user interface senses a motion of the faceplate on the two-dimensional display as user input. The user interface is adapted to sense a rotational motion of the faceplate and a translational relative motion between the faceplate and the two-dimensional display The rotational motion is defined by a rotation of the faceplate around a rotational axis being arranged perpendicular to the contact surface and/or the two-dimensional display.

Methods and systems may provide for 3D volumetric displays. Such 3D volumetric displays may include a transparent enclosed volume holding a noble gas as a gain medium. Two electrodes positioned on opposing sides of the transparent enclosed volume, may apply a voltage to excite electrons of the gain medium to an excited state. A pump laser may emit a laser beam into the gain medium at a wavelength that has an energy below an absorption line of the gain medium to allow for photon collision while also allowing the laser beam to enter the gain medium. A lens may focus the laser beam to a focused spot within the transparent enclosed volume and move the focused spot as a three-dimensionally scanned voxel to produce a 3D image.

A driving support system includes a three-dimensional (3D) projector and a driver monitoring apparatus. The driver monitoring apparatus and the 3D projector share a camera system. A camera captures an image of a driver of a vehicle, divides the captured image into a plurality of divisional captured images, and transmits the plurality of divisional captured images separately. A first controller performs a first detection process to detect first information associated with a position of an eye of the driver in response to receiving at least one of the plurality of divisional captured images from the camera. A second controller generates, in response to receiving all of the plurality of divisional captured images from the camera, a captured image by composition, and performs a second detection process to detect second information associated with a driving state of the driver.

A display device for a motor vehicle is provided. The display device includes at least one display with a display surface for displaying content via a plurality of pixels. The display device comprises a light-guiding lens with at least one entry surface and an exit surface. During operation of the display device the light emitted from the display surface enters the light-guiding lens through the at least one entry surface and is emitted by an exit surface, such that the content is shown on the exit surface. In one embodiment, the exit surface features a different shape. In another embodiment, the exit surface is a different size than the at least one display surface. In another embodiment, the display device comprises several displays with display surfaces at distances to each other, and the light-guiding lens features merely one exit surface or several exit surfaces directly adjoining each other.

A 3D display device includes a display panel, an optical element, a second communication module, and a controller. The display panel is mounted on a moving body and configured to display a parallax image. The optical element is configured to define a propagation direction of image light emitted from the display panel. The second communication module is configured to receive a motion signal indicating a parameter of a motion of the moving body. The controller is configured to cause the display panel to display the parallax image based on the parameter indicated by the motion signal.

A three-dimensional display device comprises a display panel, a parallax barrier, an acquisition section, a memory, and a controller. The display panel displays a parallax image and emit image light corresponding to the parallax image. The acquisition section successively acquires a plurality of pieces of positional data indicating user's eye positions from a detection device which detects eye positions based on photographed images which are successively acquired from a camera which images user's eyes at imaging time intervals. The memory stores pieces of positional data which are successively acquired by the acquisition section. The controller is configured to output predicted eye positions of the eyes as of a time later than the current time based on the positional data pieces stored in the memory, and cause each of subpixels of the display panel to display the parallax image, based on the predicted eye positions.