Stereoscopic systems, using active and passive three dimensional (3D) projection for creating and displaying interactive, real-time virtual stage sets, are disclosed. In one embodiment, the system uses a plurality of projectors displaying on a plurality of on-set screens, along with at least one computer processor for controlling the projectors and for maintaining, uploading, and streaming various stage set virtual imagery. The system is designed to be fully customizable for use with live stage productions, concerts, entertainment attractions, and similar events. Further, methods for innovatively using stereoscopic 3D projection technology, including both passive and active 3D visuals, in order to create an interactive, virtual environment for stage performers in real-time, are disclosed. At the core, the methods and systems apply an innovative architecture and structure for strategically placing front and rear stage projection 3D screens in conjunction with precise placement of a plurality of high lumen powered projectors.

A display backlight comprises an edge-lit lightguide having an array of light out-coupling structures to enable light to escape from the lightguide at the location of the light out-coupling structures. A light source arrangement is used for providing light into the lightguide at one or both of the opposite side edges. The light source arrangement is controllable to provide a selected one of at least first and second light outputs into the lightguide, the two light outputs having a different angle to the general plane of the lightguide and resulting in light which escapes from the lightguide with a different range of exit angles. In this way, a directional backlight output is enabled, based on the way light is coupled into a lightguide. This provides a simple structure only requiring control of the light provided to the lightguide. The backlight may for example enable an auto stereoscopic display to be formed without the need for a lenticular array.

A display method includes: processing a plurality of images to form base compositions; and presenting the base compositions with different images in a spatial arrangement which as a whole form a composite image viewable to a naked-eye viewer; wherein a subset of the plurality of images are selectively viewable as a modulated view to a user with an optical modulation device.

The disclosure relates to a medical device with a display and with a processing unit and method therefor. The processing unit is suitable for detecting states of one or more technical units of the medical device. The processing unit is further set up to control the display on the basis of detected states in order to output states of the medical device. The display is an autostereographic display. The processing unit, based on an evaluation of detected states, drives the display in such a way that a first state is visually highlighted with respect to a 3D representation, while a second state is visually not highlighted with respect to a 3D representation.

The present invention provides an open head mount display device and a display method thereof, relates to the field of head mount display technology, and can solve technical problems (such as a tedious operation, a poor display effect, an inaccurate position of the display image or the like) of the open head mount display device in the prior art. The open head mount display device of the present invention comprises: a display unit for providing a display image to user's eyes; an image acquisition unit for acquiring an image of an external object; an image analysis unit for analyzing and determining a position of the external object relative to the user's eyes in accordance with the image acquired by the image acquisition unit; and an image adjusting unit for adjusting the display image in accordance with an analysis result of the image analysis unit.

An imaging directional backlight apparatus including a waveguide, a light source array, for providing large area directed illumination from localized light sources. The waveguide may include a stepped structure, in which the steps may further include extraction features optically hidden to guided light, propagating in a first forward direction. Returning light propagating in a second backward direction may be refracted, diffracted, or reflected by the features to provide discrete illumination beams exiting from the top surface of the waveguide. Viewing windows are formed through imaging individual light sources and hence defines the relative positions of system elements and ray paths. The uncorrected system creates non-illuminated void portions when viewed off-axis preventing uniform wide angle 2D illumination modes. The system may be corrected to remove this non-uniformity at wide angles through the introduction of additional sources away from the system's object plane, additional imaging surfaces, and/or by altering ray paths.

Systems and methods for convergent 3D displays. In one embodiment, the 3D display has a display screen that includes a convergent reflector and a horizontally narrow angle diffuser. The convergent reflector focuses 2D images projected on the diffuser from an array of 2D image projectors to form viewpoints in an eyebox where one viewpoint corresponds to one projector. At a particular viewpoint, the viewer's eye sees a full-screen field of view from a corresponding projector in the array. The narrow angle diffuser diffuses incident rays projected from the 2D image projectors into narrow angular slices so that the views in the eyebox are continuously blended together. The system and methods provide advantages in that only a few projectors are required in the array to provide the viewer with a full-screen field of view and a sufficiently large eyebox for comfortable viewing.

A display device comprises a display panel (24), a light blocking arrangement for selectively blocking light which is directed to a lateral output direction from the display panel and an array of lenses (27). The display has a privacy mode in which the light blocking arrangement blocks laterally directed light output from the display device and a public mode in which the light blocking arrangement allows light to pass which is directed to a lateral output direction. The light blocking arrangement comprises a stack of layers (80), each layer comprising a pattern of light blocking arrangement portions of two different types (90,92) such that in the stack of layers, the portions align to form light blocking members, each light blocking member being aligned with an respective lens. The repeating pattern of the light blocking members has a pitch which is double the lens pitch. This enables the light blocking arrangement to be manufactured more easily.

A wagering gaming apparatus is provided, comprising a 3-dimensional (3D) display device configured to create for a player a visual illusion of a 3D scene for a wagering game, the 3D scene having perceived depth in a z-direction perpendicular to a physical screen having width in an x-direction and height in a y-direction; one or more sensor devices configured to sense a physical location of one or more anatomical features of the player; at least one processor; and at least one non-transitory processor-readable storage medium storing processor-executable instructions. The processor-executable instructions, when executed by the at least one processor, cause the at least one processor to perform various adjustments regarding the 3D scene based on the sensed physical location of an anatomical feature of the player.

A display method includes: processing a plurality of images to form base compositions; and presenting the base compositions with different images in a spatial arrangement which as a whole form a composite image viewable to a naked-eye viewer; wherein a subset of the plurality of images are selectively viewable as a modulated view to a user with an optical modulation device.