A method for pairing a key fob with a control unit is provided. The key fob executes an ID authenticated key agreement protocol with a pairing device based on a key fob identification to authenticate one another and to generate a first encryption key. The pairing device encrypts a control unit identification using the first encryption key. The key fob receives the encrypted control unit identification transmitted from the pairing device. The key fob then executes an ID authenticated key agreement protocol with the control unit based on the control unit identification to authenticate one another and to generate a second encryption key. The key fob then receives an operational key transmitted from the control unit that is encrypted with the second encryption key.

A control method applied in a display device is provided. The display device includes an image generator and a screen. The image generator is directed to output an output image. The screen is directed to operate in a first operation mode or a second operation mode. The screen has a first light-transmittance in the first operation mode and has a second light-transmittance in the second operation mode. The first light-transmittance is different from the second light-transmittance. In response to the screen operating in the first operation mode or the second operation mode, the image generator outputs the output image onto the screen in a light-emitting period and stops outputting the output image onto the screen in a non-light-emitting period after the light-emitting period.

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.

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.

A vehicle display system is disclosed. The system comprises an electro-optic device configured to switch between a mirror state and a light-transmissive state. The electro-optic device comprises a first substrate and a second substrate forming a cavity. The cavity is configured to retain an electro-optic medium that is variably transmissive such that the electro-optic device is operable between substantially clear and darkened states. The system further comprises a substantially transparent display disposed adjacent to the electro-optic device. The electro-optic device is converted to the darkened state when the substantially transparent display is emitting light.

A vehicular display device includes: a decoration panel that includes a base, the base including one surface thereof configured as a design surface and an opening formed therein, and the decoration panel being provided at an interior in a vehicle; a diffusion member that is configured to block the opening of the base; and a sheet member that includes a light transmission type screen portion, the light transmission type screen portion including a light transmitting portion and a light shielding portion mixed therein, the light transmitting portion being configured such that light that has been irradiated from a side of another surface of the base to be diffused by the diffusion member is transmitted, and the light shielding portion being configured such that the light cannot be transmitted, and the sheet member being provided on the design surface such that the light transmission type screen portion covers the diffusion member.

A mobile sensor apparatus includes a capture device for capturing vehicle movements of the vehicle and an interface for transmitting data relating to the vehicle movements to a head-worn visual output device. A display system includes the mobile sensor apparatus and the head-worn visual output device.

Described is an optical system and method for operating an HUD. The optical system includes an imaging system that generates optical radiation based on image information, a display system that projects the optical radiation, a deflection device that deflects the projected optical radiation, and at least one optically transparent pane-shaped element that at least partially reflects the deflected optical radiation. The deflection device guides the projected optical radiation onto the pane-shaped element, the optical radiation hitting the pane-shaped element at an angle. The imaging system, the display system, the deflection device and the pane-shaped element are arranged to generate a virtual image of optical radiation containing the image information. The optical system includes first and second edge points of the pane-shaped element. The first edge point has a minimal distance (d.sub.min.sup.(1)) to the deflection device and the second edge point has a minimal distance (d.sub.min.sup.(2)) to the imaging system.

The invention relates to a display device comprising a display plane, on which one or more planar display regions 10, 11 are arranged, said planar regions 10, 11 being covered by transparent coverings. A single transparent covering 3 covers all the planar display regions 10, 11 of the display device, is formed three-dimensionally on the viewer's side by regions of differing thicknesses and is connected on the side facing away from the viewer to the planar display regions 10, 11 by means of optical bonding. The refractive index of the material of the covering 3 corresponds to the refractive index of the optical-bonding material 8.

A two-layer image display device includes a back side LCD, a transparent screen, and a lower side LCD. The back side LCD displays an image on a display screen. The transparent screen is disposed on a front side of the display screen of an image display device. The lower side LCD projects an image from a lower position of the transparent screen. The transparent screen reflects, with directivity, light incident at a predetermined angle and includes an anisotropic optical film which transmits light incident at an angle other than the predetermined incident angle. The lower side LCD is disposed at a position where the image incident at the predetermined angle is projected and reflected on the transparent screen. The back side LCD is disposed at a position where incident light from an image displayed on the display screen transmits through the transparent screen.