A display control device is configured to control a display position of an image in an image projector configured to project the image onto a display object of a mobile body. The display control device includes a processor; and a memory storing instructions that, when executed by the processor, cause the display control device to perform operations including: acquiring a detection value of an acceleration acting on the mobile body; calculating an attitude angle of the mobile body based on the detection value of the acceleration; and setting a correction amount of the display position for controlling the display position of the image to be projected onto the display object by adjusting a correction amount per predetermined unit time in accordance with a change amount of the attitude angle in a predetermined period.

A display apparatus, a head-up display and a motor vehicle are provided. The display apparatus includes a projector device, a reflector structure and a light beam diffuser structure. Light emitted from the projector device passes through the light beam diffuser structure, is reflected by the reflector structure, and then reaches a first predetermined region; the light beam diffuser structure is configured to diffuse a light beam passing through the light beam diffuser structure; the reflector structure is configured to reflect the light emitted from the projector device and the light reflected by the plurality of sub-reflector structures reaches a second predetermined region within the first predetermined region if the light beam diffuser structure is removed from an optical path from the projector device to the first predetermined region, and an area of the second predetermined region is smaller than an area of the first predetermined region.

A head up display mirror holder arrangement for a motor vehicle includes a picture generation unit producing a light field. A mirror reflects the light field such that the light field is visible to the driver as a virtual image. A mirror holder has two opposite ends and an activation feature. The two opposite ends are aligned along a rotational axis of the mirror. The mirror holder retains the mirror. Each of two bushings is coupled to a respective opposite end of the mirror holder. A calibration switch has minimum proximity to the activation feature of the mirror holder.

A HUD includes a plate that connects an emission-surface of the LCD and a heat sink, is formed of a material having a higher thermal conductivity than air, and is provided with an emission-surface exhaust heat path that is formed to: include a holding region fixed to a periphery of the emission-surface directly or via a material having a higher thermal conductivity than air, and an intermediate region connecting the holding region and the heat sink; connect an end portion, which is opposite to the holding region, of the intermediate region with the heat sink directly or via a material having a higher thermal conductivity than air; extend from the emission-surface to the heat sink via the plate; and have a thermal gradient greater than that of a heat transfer path for transferring heat from the emission-surface to the heat sink by using air as a medium.

A vehicle display control device includes: a processor, the processor being configured to: acquire relay point information related to a plurality of relay points that have been set at intervals along a planned travel route of a vehicle; and display, so as to be superimposed on a foreground in a display region provided in front of an occupant, an image directed toward a planned path change point along an imaginary line connecting the relay points.

The following relates generally to providing virtual reality (VR) alerts to a driver of an autonomous vehicle. For example, a vehicle may be driving autonomously while the driver is watching a VR movie (e.g., on a pair of VR goggles); the driver may then receive a VR alert recommending that the driver take control of the vehicle (e.g., switch the vehicle from autonomous to manual mode). The following also relates to generating a VR feed for presenting real-time road conditions so that a user may preview a road segment. The following also relates to generating a VR feed corresponding to an event (e.g., a vehicle collision, a crime, a weather event, and/or a natural disaster).

A vehicle display control device includes a memory and a processor coupled to the memory. The processor is configured to acquire an actual location of a vehicle, and change information displayed at a display region generated in front of an occupant, based on the actual location of the vehicle and based on a virtual location of the vehicle on a pre-generated map.

The present invention relates to a head-up display device comprising: a. a transparent carrier comprising an inlet optical interface and an outlet optical interface, b. a reflector element arranged on one portion of the outer facet of the inlet optical interface, c. A source for projecting information, which source is capable of emitting, in the direction of the reflector element, a light beam polarized according to a main polarization and referred to as the incident beam, the incident beam arriving on the reflector element at an incidence angle and defining, with the reflector element, an incidence plane, the main polarization being a polarization contained within the incidence plane, referred to as P-polarization, the reflector element having a greater reflectivity, over a range of incidence angles including the incidence angle, for P-polarized light than for a rectilinear polarization light perpendicular to the incidence plane, which is referred to as S-polarization.

A display dimming control apparatus includes: a display image generation unit that determines a display device position that is a position of a display device that emits image light in order to display an image on a transparent screen from a display apparatus having the display device; and a dimming processing control unit that controls a dimming apparatus having a plurality of dimming elements. The plurality of dimming elements independently control a dimming level of the screen for each of a plurality of tiles obtained by virtually dividing the screen The dimming processing control unit includes a dimming position determination unit that determines one or more dimming elements that control dimming levels of one or more tiles corresponding to a screen display position.

Provided is a laminated glass having excellent heat shielding property, capable of suppressing multiple images in a head-up display, and providing better image display. The laminated glass according to the present invention includes a first lamination glass member, a first resin layer, an infrared reflective layer, and a second lamination glass member, and a laminate of the infrared reflective layer and the second lamination glass member has a small thickness, or a laminate of the infrared reflective layer and the second lamination glass member is wedge-like, or the laminated glass includes a first lamination glass member, a first resin layer, an infrared reflective layer, a second resin layer, and a second lamination glass member, and a laminate of the infrared reflective layer, the second resin layer and the second lamination glass member has a small thickness, or a laminate of the infrared reflective layer, the second resin layer and the second lamination glass member is wedge-like.