Embodiments of the present disclosure provide a display panel and a display device which enable adjustment of a light transmittance. The display panel includes a plurality of sub-pixel regions arranged into an array, at least some of the sub-pixel regions each comprising a display region configured for displaying an image and a light transmitting region configured for transparent display, and the light transmitting region is provided therein with a light adjusting device having an adjustable light transmittance.

A laminated vehicle windshield containing internal luminous information includes a first glazing, a lamination interlayer, and a second glazing with a face bearing a first curved organic-light-emitting-diode device that is configured to illuminate the first sign.

An in-vehicle video system and control method thereof, includes a display provided on an internal surface of a vehicle and configured to display a screen by receiving a video signal, a transfer unit provided on an internal side of the display with respect to the vehicle and configured to slide along a fixing member fixed to a floor of the vehicle on a frontward and rearward direction or a left and right direction of the vehicle within the vehicle, and a controller configured to determine a movement direction and a movement position of the transfer unit sliding in the frontward and rearward direction or the left and right direction and control the display and the transfer unit to transition the screen of the display in accordance with a movement path of the transfer unit based on the movement direction and the movement position of the transfer unit.

A vehicle includes a vehicle body having a cabin, a first seat and a second seat arranged in the cabin, a planar transparent member placed on a side surface of the cabin, and that separates an interior of the cabin and a vehicle exterior from each other, and a display device placed on the side surface of the cabin and arranged along the planar transparent member, the display device having a plurality of pixels. At least a part of the display device is placed on the side surface and between the first seat and the second seat.

A vehicle display assembly may comprise a transparent element defining a viewing surface, a display element disposed behind the transparent element, and a printed circuit board in electrical communication with the display element. The display element is configured to generate an image visible through the transparent element. The vehicle display assembly may be in communication with at least one of a vehicle sensor and a vehicle computer. The images appearing in the display element may change orientation based on the presence or absence of a vehicle occupant.

Vehicle visual systems are disclosed to produce seamless and uniform surround-view images of the vehicle using a number of Ultra Wide-Angle (UWA) lens cameras and optionally HUD systems. A distributive system architecture wherein individual cameras are capable of performing various image transformations allows a flexible and resource efficient image processing scheme.

A vehicle interior layout includes a console having a support structure configured to be mounted on the floor of the vehicle and topped by an upper part, the upper part being rotatable around a substantially vertical pivot axis (A).

A control unit, in a disclosed embodiment, includes a transceiver, memory, and a processor. The processor is coupled to the transceiver and memory and executes instructions from the memory to cause the control unit to receive a first transmission containing a certificate, verify the authenticity of the certificate, and, after verifying authenticity of the certificate, execute a public key agreement protocol to generate a first common secret encryption key, receive a second transmission containing an encrypted first public key that is encrypted by the first common secret encryption key, decrypt the encrypted first public key using the first common secret encryption key to determine the first public key, execute a public key agreement protocol to generate a second common secret encryption key, generate an operational key, encrypt the operational key using the second common secret encryption key, and transmit the encrypted operational key.

Often when there is a glare on a display screen the user may be able to mitigate the glare by tilting or otherwise moving the screen or changing their viewing position. However, when driving a car there are limited options for overcoming glares on the dashboard, especially when you are driving for a long distance in the same direction. Embodiments are directed to eliminating such glare. Other embodiments are related to mixed reality (MR) and filling in occluded areas.

The systems and methods provided herein are directed to providing an touch interface on a transparent vehicle window by selectively providing current to an electro-reactive dye embedded within the window. Capacitive touch sensors relay user interaction with the display and allow for control of selected vehicle and device functions by means of the window display. The window display adapts to the user's position and the position of the window by altering the display position.