A stereoscopic image display device includes a display panel including a first display area and a second display area. A variable light-transmitting structure is disposed on the display panel and forms a blocking area blocking light from the display panel and a transmitting area transmitting the light from the display panel within the first display area by time division. A lens array is disposed on the variable light-transmitting structure and forms a light field by refracting the light from the display panel.

A stereoscopic image display device includes a display panel including a first display area and a second display area. A variable light-transmitting structure is disposed on the display panel and forms a blocking area blocking light from the display panel and a transmitting area transmitting the light from the display panel within the first display area by time division. A lens array is disposed on the variable light-transmitting structure and forms a light field by refracting the light from the display panel.

Systems and methods are described for providing a display. In some embodiments, a display device includes a light-emitting layer with an addressable array of light-emitting elements such as OLEDs. A flexible optical layer overlays the light-emitting layer. The flexible optical layer has a plurality of lens regions, where optical powers of the lens regions change in response to changing levels of tensile or compressive force on the flexible optical layer. When no force is applied, the lens regions may have no optical power, and the display may operate as a 2D display. When force is applied (e.g. by bending the display), the lens regions may operate as cylindrical lenses in a lenticular array, and the display may be operated as a 3D multiview display.

A display processor and computer-implemented method are provided for processing three-dimensional [3D] image data for display on a 3D display. The 3D display is arranged for emitting a series of views of the 3D image data which enables stereoscopic viewing of the 3D image data at multiple viewing positions. The series of views may be displayed on the 3D display using overscan. The degree of overscan may be determined as a function of one or more depth range parameters, the one or more depth range parameters characterizing, at least in part, a degree of depth perceived by a viewer when the series of views is displayed on the 3D display.

A display processor and computer-implemented method are provided for processing three-dimensional [3D] image data for display on a 3D display. The 3D display is arranged for emitting a series of views of the 3D image data which enables stereoscopic viewing of the 3D image data at multiple viewing positions. The series of views may be displayed on the 3D display using overscan. The degree of overscan may be determined as a function of one or more depth range parameters, the one or more depth range parameters characterizing, at least in part, a degree of depth perceived by a viewer when the series of views is displayed on the 3D display.

Lenticular lens assembly for attachment to a display area

The invention relates to a prefabricated lenticular lens assembly (10) for attachment to a display area (100), having: a lenticular lens layer (14) comprising a first surface (20) having a plurality of curved lens portions (22) and a second surface (18) facing away from the first surface (20); a cover layer (12) which faces the first surface (20) of the lens layer (14) at least in some regions; a carrier layer (16) which faces a second surface (18) of the lens layer (14) at least in some regions;
wherein the lenticular lens layer (14), the cover layer (12) and the carrier layer (16) are already at least indirectly connected to each other before the assembly (10) is attached to the display area (100).

The invention further relates to a method for producing a lenticular lens assembly (10).

Lenticular lens assembly for attachment to a display area

The invention relates to a prefabricated lenticular lens assembly (10) for attachment to a display area (100), having: a lenticular lens layer (14) comprising a first surface (20) having a plurality of curved lens portions (22) and a second surface (18) facing away from the first surface (20); a cover layer (12) which faces the first surface (20) of the lens layer (14) at least in some regions; a carrier layer (16) which faces a second surface (18) of the lens layer (14) at least in some regions;
wherein the lenticular lens layer (14), the cover layer (12) and the carrier layer (16) are already at least indirectly connected to each other before the assembly (10) is attached to the display area (100).

The invention further relates to a method for producing a lenticular lens assembly (10).

A stereoscopic image display device includes a flat panel display unit, a lens array unit, and a light guide structure unit. The light guide structure unit includes a light guide microstructure. The light guide microstructure is disposed on a side of the lens array unit. A bottom angle of the light guide microstructure is defined as B, and a bottom length of the light guide microstructure is defined as P. The bottom angle B and the bottom length P of the light guide microstructure satisfies following conditions: (i) 15.5 degrees≤B≤83.5 degrees; and (ii) 10 micrometers≤P≤2,000 micrometers, such that an oblique viewing angle of the stereoscopic image display device falls within a range from 10 degrees to 60 degrees.

A stereoscopic image display device includes a flat panel display unit, a lens array unit, and a light guide structure unit. The light guide structure unit includes a light guide microstructure. The light guide microstructure is disposed on a side of the lens array unit. A bottom angle of the light guide microstructure is defined as B, and a bottom length of the light guide microstructure is defined as P. The bottom angle B and the bottom length P of the light guide microstructure satisfies following conditions: (i) 15.5 degrees≤B≤83.5 degrees; and (ii) 10 micrometers≤P≤2,000 micrometers, such that an oblique viewing angle of the stereoscopic image display device falls within a range from 10 degrees to 60 degrees.

A system and method for the projection of virtual 3-D images onto a surface with perspective shifting viewing capability including: a source of data for at least two different paired left-right view sets of one subject, an image reflecting surface, and a projector capable of simultaneously projecting pairs of left-right view sets, and capable of changing projected left-right view sets of images from a first set to a second set to create a stereopsis effect in which content of a complete projected image appears to move in perspective.