A display device for a vehicle includes: a first transparent or translucent layer comprising a pictogram, a second transparent or translucent layer, covering the pictogram, a liquid crystal display, arranged in line with the pictogram, and a light source configured to emit light to illuminate the pictogram by passing through the liquid crystal display and the second layer. The liquid crystal display at least partially covers the second layer, and an assembly formed by the first layer and the second layer is rigid.

The invention is a robust lensless instrument cluster configured for installation in a vehicle. The instrument cluster comprises an outer case, a PCB and lighting structure, an inner frame, an optical bonding assembly, halo lighting portions, a seamless display comprising tell-tale indicators and gauges, and an outer visor. The instrument cluster further comprises a plurality of LEDs for compartmentalized and indirect lighting of the tell-tale indicators on the seamless display and the halo lighting portions around the edges of the seamless display. Because the instrument cluster is lensless and otherwise exposed to the environment, it comprises a seal system to prevent the ingress of water and dust into the interior components. The seal system can also eliminate the risk of mura in the optical bonding assembly.

The invention relates to a function display (1) for selectively displaying several symbols representing one switching function, respectively, and/or at least two switching states, respectively, comprising: a light guide stack which, given an attachment of the function display (1) as intended, forms a display surface (8) facing towards the observer (B); wherein the light guide stack is formed from at least two transparent or translucent, planar light guides (2, 3) arranged in an overlaid manner in a stacking direction, which are arranged so as to be spaced apart by a transparent or translucent layer consisting of a material that is optically thinner compared to the adjacent light guides (2, 3), preferably an air gap (14), so that the light guides (2, 3) each have a main surface (H) facing towards the observer (B) and a main surface (H′) facing away from the observer (B), and, in at least one light guide (2), the main surface (H′) facing away from the observer (B) faces towards a light guide (3) which is most closely adjacent in the opposite direction to the stacking direction;

at least one light source (5, 5′) per light guide (2, 3), which is arranged such that in each case, its light (L, L′), via an end face (11) of an associated light guide (2, 3) facing towards the light source (5, 5′), is coupled into the respective light guide (2, 3); wherein, further, at least one microstructured symbol area (12a, 12b) provided in or on the light guide (2, 3) is provided for each light guide (2, 3), which is configured, if the light source (5, 5′) is respectively activated, to be visible, illuminated by the light (L, L′) coupled into the light guide (2, 3), to the observer (B); a circuit board (7) on which the several light sources (5, 5′) are arranged and fixed; a panel (6) fixed to the light guide stack by substance-to-substance connection and/or non-positively and/or positively, to which the circuit board (7) is fixed while resting against a mounting surface (15), wherein two light sources (5′) of the circuit board serve as an alignment aid in attaching the circuit board (7) and the panel (6); and an associated assembly method.

A vehicle rearview mirror assembly is provided, including: a casing including a first shell body and a mounting board having an attachment portion with an aperture; a mirror attached to the mounting board and including a light-penetrable patterned portion spatially corresponding to the aperture; a light emitting module mounted to the attachment portion and including a second shell body, a light guide and a light source, the second shell body including an insertion slot therethrough, the light source being inserted through the insertion slot and engaged within the second shell body, and a binding member securing the light emitting module to the second shell body and sealing the insertion slot.

A display system for at least one wheel of at least one vehicle comprising: At least one LED display device for displaying information on a wheel of a vehicle; A computer in association with the at least one LED display device, the computer comprising GPS; A main server;
Wherein the LED display device is linked to the computer and the computer is in wireless communication with the main server via a wireless network; in use, the server has stored in memory a plurality of information packets for display by the LED display device, each information packet has an associated location and/or time for being displayed, the main server wirelessly sends at least one information packet and associated time and/or location to the associated computer of the at least one vehicle, when the at least one vehicle is in the desired location and/or time the computer instructs the at least one LED display device to display the associated information.

An operating method of an optical system in a vehicle is provided. The optical system includes a display device. The display device includes a display panel and a plurality of light emitting units. The light emitting units are configured to emit a light to the display panel. The operating method includes the following steps. An emphasized portion of an object is determined. An image corresponding to the emphasized portion is displayed by the display device by adjusting a light intensity of at least a portion of the light emitted from the light emitting units.

The present disclosure provides a curved-surface vehicle-mounted display module, a vehicle-mounted display device and a vehicle. The curved-surface vehicle-mounted display module includes a back plate, a backlight assembly and a liquid crystal panel. The back plate is configured to support the backlight assembly and the liquid crystal panel. The backlight assembly includes a flexible substrate and LEDs. The flexible substrate includes at least one backlight block, each backlight block is provided with a plurality of LEDs, and a distance between two adjacent LEDs is a predefined value.

A vehicle communication system installed in a vehicle includes: a lamp for illumination, a display or signal; a display that is configured by a planar light emitter and has an information display function; and a control unit that is capable of controlling turning-on of the lamp and of the display. The control unit is configured to control the lamp and the display in a linked manner, and present vehicle information indicating a condition of the vehicle by combining light emission of the lamp with information display of the display.

A vehicle interior component comprising a cover with a surface providing a display region is disclosed. The component may comprise a composite layer/structure and light source to provide light at a first and a second visible color/wavelength. The composite layer may comprise light-transmissive segments with color and light-transmissive transparent/translucent segments; light at the first wavelength is transmitted through a first segment and transparent/translucent segment to present a first image/visual effect at the display region; light at the second wavelength is transmitted through a second segment and transparent/translucent segment to present a second image/visual effect at the display region; light at the first wavelength is obstructed by the second segment; light at the second wavelength is obstructed by the first segment; transparent/translucent segments transmit light at first and second wavelengths. The composite layer may comprise a multi-layer form on the cover.

Provided is a smart garnish installed on an automobile interior material (a door trim, an instrument panel, a console, or the like), and to a smart garnish for an automobile which is driven when a capacitance change is sensed by a pressed deformation of an upper case through a capacitive touch sensor pad formed of a ground (GND) and capacitive touch sensors corresponding to symbols and capacitive force sensors distributed corresponding to the ground and thus the touch and force of the desired symbol are sensed without noise.