A head-up display device including a display unit, a polarization beam-splitting module, and an optical module is provided. The polarization beam-splitting module receives a first image beam and a second image beam from the display unit, and transmits the first image beam and the second image beam to the optical module. The first image beam and the second image beam are respectively reflected by the optical module to an outside of the head-up display device, and then transmitted to a target element, to form a first virtual image and a second virtual image. By the polarization beam-splitting module, an optical path length of the first image beam from the display unit to a position of the first virtual image formed by itself is longer than an optical path length of the second image beam from the display unit to a position of the second virtual image formed by itself.

A display device includes a display configured to display a video, a concave mirror configured to reflect a video display light of the video displayed on the display toward a reflection part that is formed in a curved shape and that faces a viewer, and a housing in which the display and the concave mirror are assembled, wherein an angle of the concave mirror with respect to the housing is adjustable by rotating the concave mirror on a reference plane of the housing in accordance with a relative positional relationship among the housing, the reflection part, and the viewer.

A vehicle light-adjusting window and a vehicle light-adjusting window system capable of clearly projecting a video are provided. A vehicle light-adjusting window includes a transparent plate, a first conductive film, a light-adjusting layer, a second conductive film, and a projection film, which are arranged in this order.

A head-up display device as a vehicle display device projects display light onto a front windshield of a vehicle, displays a virtual image by reflected display light, on the front windshield, so as to be superimposed on a real scene transparent through the front windshield, captures an image of a driver of the vehicle by projecting infrared light onto the driver, and detects the positions of the eyes of the driver based on the captured image. A control unit detects the position of a feature point of the face of the driver in the captured image and stores a positional relationship with the detected positions of the eyes, and, when it is difficult to detect the positions of the eyes in die captured image, estimates a viewpoint position of the driver based on the position of the feature point detected at this time and the positional relationship stored beforehand.

A head-up display includes a picture generation unit configured to emit first light for generating a first picture at a position away from a vehicle by a predetermined distance and second light for generating a second picture at a position away from the vehicle by a distance different from the predetermined distance; and a reflection unit configured to reflect the first light and the second light so that the first light and the second light are radiated to a windshield. A first optical element that reduces transmittance of light including at least visible light to be lower than transmittance of the first light is provided between the picture generation unit and the windshield at a position through which the second light passes.

A trim panel intended to be arranged within the interior of a vehicle cabin, the trim panel having an appearance face intended to be visible to an occupant of the cabin, a reverse face provided with an interface for attachment of the trim panel to a support member, and at least one attachment bracket forming part of the attachment interface. The appearance face defines a tactile interaction area intended to serve as a control input for the occupant, and at least one sensor assembly is arranged on an attachment bracket, each sensor assembly being adapted to, when the trim panel is arranged inside a cabin, detect a deformation of its attachment bracket upon pressure exerted by an occupant on the trim panel on the tactile interaction area.

Vehicle projection assemblies are described. In particular, vehicle projection assemblies within a housing including a projection module, and selective reflective polarizing element are described. Particular selective reflective polarizing elements may enable advantageous configurations for such vehicle projection assemblies.

A display control device that includes: a processor; and a memory that is coupled with the processor and is configured to store a correspondence relationship between an angle of a mirror configured to reflect light for display on a display and depth information indicating a virtual display position of an image for display on the display so as to correspond to an external scene, the processor being configured to: receive input from a user, and change the mirror angle in response to the received input, adjust a display position of an image to be displayed on the display based on the depth information associated with the mirror angle after it is changed, and display the image on the display.

An aerial display device is mounted on a vehicle and displays information toward a driver seated in a driver seat of the vehicle. The aerial display device includes a display panel and a reflector array. The display panel including a display surface that emits images as light, the display panel being orientated such that the display surface faces toward the driver seat, the display surface including a screen display area and an aerial display area located next to the screen display area. The aerial display area is located at the upper edge portion of the display surface in an installed orientation. The screen display area is a part of the display surface located below the aerial display area. The reflector array forms the light emitted from the aerial display area as an aerial display image in midair above to the aerial display area.

A projection display device includes a display device, an optical system, and a shielding plate. The optical system includes a first mirror and a second mirror provided on the regular optical path, the second mirrors being to provide an optical path convergence point on the regular optical path, and the first mirrors being provided at a position corresponding to the optical path convergence point. The projection display device is configured such that a position of a mirror surface of the first mirror and the second mirror is adjustable in accordance with a position of an eye point of a user so as to project the light toward the projection position that corresponds to the position of the eye point. The shielding plate is provided such that the shieling plate does not interfere with the regular optical path and such that the shielding plate interferes with the different optical path.