Embodiments are disclosed for display configurations for providing an augmented reality heads up display. In one example, a method of operating a display system includes adjusting an output of image light from a display to pass through an optical element positioned between the display and at least one micro lens array, including impinging light upon a transparent plane to generate a three-dimensional image on a continuous plane that is based on a user focal point determined by an eye-tracking module.

A display system includes a display unit, a housing, and a reflecting optical system. The display unit displays an image based on a captured image. The housing includes a housing room that houses the display unit and the reflecting optical system. The reflecting optical system reflects the image displayed on the display unit, thereby outputting the reflected image through an opening of the housing to the outside of the housing.

Embodiments of this disclosure pertain to a vehicle interior system comprising a base having a base surface; and a glass article coupled to the surface, wherein the glass article comprises a first portion comprising a first elastically deformed surface forming a first concave shape with a first radius of curvature from about 20 mm to about 2000 mm, and a second elastically deformed surface directly opposite the first elastically deformed surface that forms a second convex shape, wherein the second elastically deformed surface has a surface compressive stress that is less than a compressive stress at the first elastically deformed surface, and a second portion adjacent the first portion, wherein the second portion is substantially planar portion or curved.

An electro-optic element includes first and second spaced-apart transparent substrates defining respective opposite, aligned first and second edges, a first bus including a first electrode disposed along an inner surface of the first substrate adjacent the first edge and a second electrode disposed along an inner surface of the second substrate adjacent the first edge, and a second bus including a first electrode disposed along an inner surface of the first substrate adjacent the second edge and a second electrode disposed along an inner surface of the second substrate adjacent the second edge. The first bus and second bus are spaced apart along widths of the first and second substrates between the respective first and second edges. An electro-optic medium is disposed between the first and second transparent substrates, including between the first and second electrodes of the first bus and the second bus, respectively.

Disclosed is a touch display device and a manufacture method thereof. The touch display device includes a display panel and a touch module stacked together. The touch module includes a first electrode layer, a light absorbing layer and a second electrode layer sequentially stacked on a surface of the display panel. The first electrode layer includes a plurality of first touch electrodes arranged at intervals in a first direction; the light absorbing layer includes a plurality of first sub-light absorbing layers arranged at intervals in the first direction; at least one of the plurality of first sub-light absorbing layers corresponds to at least one of the plurality of first touch electrodes and is on a side of a corresponding first touch electrode facing away from the display panel; and the second electrode layer includes a plurality of second touch electrodes arranged at intervals in a second direction; the first direction intersects the second direction.

A display module for use as a front dashboard, a center console, a passenger entertainment display, or an instrument panel is described. The display module includes a display assembly that is joined to a cover lens via an optically clear adhesive layer. The display assembly is arranged as a flat planar device, and the cover lens is arranged as a curved planar surface that includes an inner laminate sheet that is joined to an outer laminate sheet via a second adhesive layer.

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.