Abstract: An optical product that includes a transparent lens sheet, which has a first side with a plurality of side-by-side sets of linearly arranged lenses. Each of the sets of lenses is at a slant angle in the range of 10 to 46 degrees from a vertical or a horizontal axis of the lens sheet. The product includes an image layer that includes pixels from a number of digital images. The pixels are arranged in a pattern of pixel locations providing non-orthogonal interlacing of the digital images relative to each of the sets of the linearly arranged lenses. The pattern of pixel locations aligns a number of the pixels from each of the digital images to be parallel to a line extending through a center of the linearly arranged lenses in each set. Each of the linearly arranged lenses may have a round base, a hexagonal base, or a square base.

Abstract: Integral imaging 3D films for use with a display panel. The films include a flexible transmissive substrate having a first surface on a viewer side and a second surface for placement on the display panel. Convex lenses are located on the first surface. The second surface is planar for a plano-convex design or has concave lenses registered with the convex lenses for a convex-concave compound lens design. In the plano-convex design, the lens focus is in front of or behind the pixels. In the convex-concave design, the convex and concave lenses combined focus is in front of, at, or behind the pixels. In use the 3D films produce 3D images with motion parallax.

Abstract: Disclosed herein is a patterned retarder film for 3D display. The patterned retarder film includes a substrate, a patterned retarder layer and a micro-louver structure. The patterned retarder layer on the surface of the substrate has a plurality of first retardation micro structures and a plurality of second retardation micro structures and can split the image into two phase of images to form stereo image; the micro-louver structure is disposed between the substrate and the patterned retarder layer at the boundary of the first retardation micro structures and the second retardation micro structures. The micro-louver structure can decrease the crosstalk of the 3D display at vertical viewing angle and does not decrease the brightness of the 3D display at normal viewing angle.

Abstract: The present invention discloses a micro-optical phase film and a micro-lenticular lens. The optical phase film is integrally formed and includes an optical phase film base and a concave surface disposed on the optical phase film base. The concave surface has a plurality of concave and semi-cylinder like protrusions which are separated from each other in a constant pitch and have the same height. A lens layer covers the optical phase film to form a micro-lenticular lens. The optical phase film will exhibit different refractive index because of the incident light with different polarization angles, so as to achieve the object of 2D/3D image switching.

Abstract: A stereoscopic image display device includes: a display panel on which pixels each constituted with a plurality of sub-pixels formed with electro-optic elements by corresponding to parallax images are arranged in matrix; and an optical module which distributes light emitted from the pixels arranged in the first and second directions to different directions from each other along the first and second directions, respectively. The display panel includes first and second non-control regions which are the regions existing between boundaries of apertures of the sub-pixels where control of electric-optic conversion cannot be done. An intersection part of the first and second non-control regions is disposed on a lattice point that is an intersection point of segments in a unit lattice constituted with lattice lines, and the first or the second non-control region is bent at least once within the unit lattice with respect to the lattice lines.

Abstract: A stereoscopic image display device includes: a display panel in which pixels each constituted with N×N pieces (N is a natural number of 2 or larger) of sub-pixels colored in M (M is a natural number of 1 or larger) primary colors are arranged in matrix; and an optical separation module in which optical elements which distribute exit light from each of the pixels according to parallax images in a first direction and a second direction along layout of the pixels are arranged by being corresponded to each of the pixels. The neighboring sub-pixels within the pixels are of different colors, array pitches of the sub-pixels are uniform in the first and second directions, same numbers of the parallax images are displayed for the first direction and the second direction within the pixels, and numbers of the sub-pixels in different colors within the parallax images are equivalent.

Abstract: According to an embodiment, an image display device includes an optical element, a voltage controller, and a display. Regarding the optical element, the refractive-index distribution changes according to the voltage applied thereto. The voltage controller controls, in a first mode, the voltage applied to the optical element in such a way that a first-type refractive-index distribution is achieved which acts as a first-type Fresnel lens; and controls, in a second mode that is different than the first mode, the voltage applied to the optical element in such a way that a second-type refractive-index distribution is achieved which acts as a second-type Fresnel lens having a greater number of steps than the first-type Fresnel lens. The display is disposed on the back side of the optical element and displays images.

Abstract: A display displays a composite image including element pixels. Each element pixel is formed by arranging, in a direction, pixels respectively extracted from images having different viewpoints. A first optical element includes lenses arrayed in the direction to correspond to the element pixels and emits in parallel light rays emitted from pixels respectively included in the element pixels, for a particular image. A second optical element condenses the light rays. An output circuit selects a pixel of the particular image which is included in a particular element pixel and outputs its pixel value to the display. At this time, a pixel more distant from an optical axis of the second optical element along the direction in the particular image is selected as a distance between the first and second optical elements becomes smaller than a focal length of the second optical element.

Abstract: An automated lenticular photographic system includes an interface that permits a user to upload image files and image processing and printing equipment that is in communication with the interface for receiving the uploaded image files and processing the uploaded image files to create an interlaced print image file that is used to produce an interlaced print sheet containing interlaced print images. A pair of registration marks is formed on the interlaced print sheet outside of borders of the interlaced print images. The system also includes a processing station where the interlaced print sheet is aligned with a lenticular lens sheet with a registration system that detects whether the lenticular lens sheet is off-centered and skewed relative to the interlaced print sheet. The system also includes means for controllably adjusting the position of the lenticular lens sheet relative to the interlaced print sheet until proper registration between the lenticular lens sheet and the interlaced print sheet is achieved.

Abstract: A display apparatus to be inspected includes: a display panel in which pixel groups are arranged; and an optical element for providing image display for N viewpoints (N is a natural number more than one) from the pixel groups. An inspection apparatus includes: a image output device for outputting a test pattern including image signals different in the respective viewpoints to the display apparatus; and an extraction device for extracting the slope and the position of a boundary line segment in an inspection image displayed on the display apparatus. The extraction device detects positional accuracy between the display panel and the optical element on the basis of the slope and the position extracted by the extraction device.

Abstract: A glasses-free reflective 3D color display includes a reflective color display configured to display a reflective color image by using light entering from the outside and configured to form a left eye image and a right eye image, and a lens array configured so that each lens corresponds to a pair of pixels of the reflective color display and configured to separate the left eye image and the right eye image formed in the reflective color display.

Abstract: A display device includes: a display unit including a first surface having a curved surface shape which is a straight line in a first direction and is a curved line in a second direction orthogonal to the first direction; and a parallax adjustment unit that includes a second surface having a curved surface shape which is a straight line in the first direction and is a curved line in the second direction, and is arranged on an image-displaying surface side of the display unit, wherein a distance between the first surface and the second surface at center in the second direction is shorter than a distance between the first surface and the second surface at an end in the second direction.

Abstract: Disclosed is a lens grating comprising: a plurality of lens units arranged in a column, any two adjacent lens units having a transparent spacer therebetween, the transparent spacers in the column comprising odd-number spacers and even-number spacers, wherein the odd-number spacers only allow light emitted from first images to transmit through to a first viewing area, and the even-number spacers only allow light emitted from second images to transmit through to a second viewing area The lens units are adapted to refract the light emitted from the first images and the light emitted from the second images respectively to the first viewing area and the second viewing area. A display device is also disclosed, the display device comprising the above lens grating and a display module.

Abstract: Disclosed is an imaging directional backlight apparatus comprising a waveguide, a light source array, and a further optical element for providing large area directed illumination from localized light sources. The imaging directional backlight may comprise a stepped waveguide that 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. The further optical element may comprise a superlens comprising first and second aligned lens arrays that may be arranged to modify the output viewing windows to achieve enhanced window imaging from the directional backlight.

Abstract: Various embodiments are generally directed toward a viewing device using and steering of collimated light to separately paint detected eye regions of multiple persons to provide them with 3D imagery. A viewing device includes an image panel to cause collimated light to convey multiple pixels of one of a left side frame and a right side frame associated with a frame of 3D imagery, and a steering assembly to steer the collimated light towards an eye to paint an eye region of a face that includes the eye. Other embodiments are described and claimed herein.

Abstract: A translucent liquid crystal display panel (2) includes pixel pairs as display units each formed by a left-eye pixel (4L) and a right-eye pixel (4R) and arranged in a matrix shape. A through hole (4Ld) arranged in a color layer (4Lc) of a color filter has a slit shape whose longitudinal direction is identical to the orientation direction of a cylindrical lens (3a) constituting a lenticular lens (3). Similarly, a through hole (4Rd) arranged in a color layer (4Rc) of a color filter has a slit shape whose longitudinal direction is identical to the orientation direction of the cylindrical lens (3a) constituting the lenticular lens (3). This suppresses the phenomenon that a hue is changed by a field-of-view angle and/or an external light condition on the translucent display panel capable of displaying an image directed to a plurality of viewpoints.

Abstract: A display including an electrowetting prism array is provided. The display includes: a light source, a 2-dimensional (2D) display for providing an image using light from the light source, a prism array in which a refractive power of one or more prisms of the prism array is adjustablein real time, and an optical element which increases a refraction of light transmitted therethrough. In the display, the optical element may be disposed in front of or behind the prism array. The optical element may be a convex lens, a Fresnel lens, a holographic optical element (HOE), a diffraction optical element (DOE), or a second electrowetting prism array. The convex lens may be a variable focus lens.

Abstract: A three-dimensional (3D) display system is provided for displaying a 3D image. The 3D display system includes a display panel having pixels arranged at a pixel spatial period and a lens grating disposed together with the display panel. The lens grating further includes a plurality of lens units arranged at a first period and a plurality of non-lens units arranged at a second period. The second period is greater than one-third of the first period and less than two-thirds of the first period, and the plurality of lens units and the plurality of non-lens units are arranged such that the lens grating has a different spatial period from the pixel spatial period to reduce Moire fringe effect between the lens grating and the pixels of the display panel.

Abstract: According to one embodiment, an apparatus includes a projection unit, a change unit, and a separation unit. The projection unit projects first rays containing parallax image components. The change unit receives the first rays projected from the projection unit, collimates the first rays, and causes second rays to emerge. The separation unit receives the second rays emerging from the change unit, separates the parallax image components contained in the second rays at angles corresponding to the parallax image components, and projects the parallax image components to a viewing area. The separation unit includes a lenticular lens in which cylindrical lens elements are arrayed and boundaries are set between adjacent cylindrical lens elements. The parallax image components pass through areas of the cylindrical lens elements except for the boundaries.

Abstract: A method interlacing of images into an interlaced print file for controlling an output device. The interlacing method involves arranging a set of pixels in a line that is traverse but non-orthogonal to the longitudinal axis of a slant lens or lenticule. Each of these pixels is associated with a different frame/image, e.g., six or more frames are used in each interlaced image, with one being visible through the lens or lenticule at a time by a viewer. The slant lens interlacing method does not involve slicing each frame and the splicing these slices together. Instead, individual pixels from each frame are combined within a digital print file in a unique pattern to provide the non-orthogonal interlacing described herein (e.g., the new interlacing may be considered “matrix interlacing” or “angular-offset interlacing”), and a significantly larger amount of information is presented under each slant lens.

Abstract: A lenticular system for autostereoscopic display devices in which a transparent polymeric lenticular array is embedded between two glass sheets and the gap between the polymeric lenticular array and the outer cover is filled with a transparent polymeric filling having a refractive index different than the refractive index of the polymeric lenticular array to reduce glare.

Abstract: A display apparatus including a backlight module, a filtering module and a display panel is provided. The backlight module includes a plurality of sets of light emitting devices. Each set of light emitting devices includes at least one first color light emitting device and at least one second color light emitting device. The filtering module is disposed on a transmission path of light emitted by the plurality of sets of light emitting devices and includes a plurality of sets of filtering units. Each set of filtering units is configured to allow light emitted by one set of light emitting devices to pass through. The display panel is disposed on the transmission path of the light emitted by the plurality of sets of light emitting devices. The backlight module turns on the plurality of sets of light emitting devices by turns.

Abstract: A lenticular display device is described that is effective in increasing both perceived angular resolution and spatial resolution. These desirable results are achieved by modifying the lenslet array to better match the content of a given light field. An optimization algorithm or method (which may be implemented with software run on a computing device) is provided that analyzes an input light field and computes an optimal lenslet size, shape, and arrangement of sets of lenslets across the width of the array to better (or even best) match the input light field given a set of output parameters. The resulting lenticular display device (or print) shows higher detail and smoother motion parallax compared with fixed-size lens arrays. The usefulness of these content-adaptive lenticular prints has been demonstrated or proven using rendered simulations, by generating 3D-printed lens arrays according to the present description, and with user studies.

Abstract: In one implementation, a system includes a multi-core processor and an optical display with a plurality of hogels. Each hogel is configured to radiate light in a plurality of directions, with controllable intensities in each of the plurality of directions. The multi-core processor is coupled to the optical display and configured to control the hogels. The multi-core processor includes at least two cores, an on-chip memory, and a master processor in a single integrated circuit package. The master processor may be a general-purpose on-chip processor, such as a core in the multi-core processor, that is used to coordinated operations of the other cores. Each of the cores is configured to receive hogel data and to generate signals for a corresponding subset of the plurality of hogels.

Abstract: An image display apparatus having sub-pixels of four colors is provided in which the resolution when an image is two-dimensionally displayed is not affected, and deterioration in the color balance of a three-dimensionally displayed image is suppressed. In the image display apparatus, the arrangement of a sub-pixel for displaying red for a left eye and a sub-pixel for displaying green for a right eye has been replaced with the arrangement of a sub-pixel (Lg1) for displaying green for the left eye and a sub-pixel (Rr1) for displaying red for the right eye. The arrangement of a sub-pixel for displaying blue for the left eye and a sub-pixel for displaying yellow for the right eye has been replaced with the arrangement of a sub-pixel (Lx1) for displaying yellow for the left eye and a sub-pixel (Rb1) for displaying blue for the right eye. Replacement with the sub-pixel and the sub-pixel and replacement with the sub-pixel and the sub-pixel are made for every other pixel.

Abstract: The 3D display device includes a display panel including a first pixel area displaying a left-eye image, and a second pixel area neighboring the first pixel area and displaying a right-eye image, and a lenticular lens unit positioned on the display panel to cover the first pixel area and the second pixel area and having at least one color.

Abstract: Provided are a 3D display device and a method of manufacturing the same. The 3D display device includes a curve-shaped display panel displaying an image, and a curve-shaped lenticular lens disposed in front of or behind the display panel. A left-eye image displayed by the display panel is presented to a user's left eye through the lenticular lens, and a right-eye image displayed by the display panel is presented to a user's left eye through the lenticular lens.

Abstract: The present disclosure describes systems and methods for enhancing the brightness characteristics of a three-dimensional (3-D) image viewing apparatus. According to embodiments of the present disclosure, a 3-D image viewing apparatus may comprise a frame, a first lens disposed within the frame and a second lens disposed within the frame. The first lens may transmit light within a blue spectrum, a green spectrum, and a red spectrum at a first pre-determined intensity. The second lens may transmit light within an amber spectrum and an offset spectrum at a second pre-determined intensity. In certain embodiments, the offset spectrum may comprise a violet spectrum.

Abstract: A lens component 10 comprises K unit lenses 11, each extending in the X direction and having a common structure, arranged in parallel at a minimum period PL in the Y direction. Each unit lens 11 includes two partial lenses 121, 122 sectioned within the minimum period PL in the Y direction and a flat part 13 disposed between the partial lenses 121, 122. The partial lenses 121, 122 have respective optical axes different from each other but parallel to the Z direction and form images of a common point on an object surface onto an image surface A at respective positions different from each other.

Abstract: Disclosed are a colour filter substrate, a manufacturing method therefor and a 3D display device. The colour filter substrate comprises a substrate, a colour filter unit and a cylindrical lens structure between the substrate and the colour filter unit.

Abstract: Provided are a complex spatial light modulator and a three-dimensional image display device including the same. The complex spatial light modulator includes: a spatial light modulator for modulating a phase of light; a prism array disposed next to the spatial light modulator; and a polarization-independent diffractive element for diffracting light that has passed through the prism array. The complex spatial light modulator may modulate both phase and amplitude of light.

Abstract: An apparatus for providing a dimensional display such as a 3D effect without special-purpose glasses. The apparatus includes a foreground display assembly including a first planar display element with a front surface and an opposite back surface. Additionally, the apparatus includes a background display assembly including: (a) a second planar display element spaced apart from and parallel to the first planar display element; and (b) a light source backlighting a back surface of the second planar display element. The first and second display elements are emissive display units and concurrently display frames of a foreground image stream and corresponding frames of a background image stream. The first display element may be a transparent LCD panel, and the output light from the front surface of the second display element provides backlighting for the first display element such that foreground images are backlit by output light of the second display element.

Abstract: An autostereoscopic display device has display elements, each of which has an output light intensity distribution which has at least two non-zero light intensity levels, comprising a first light intensity at the centre of the display element area and a second lower light intensity at a periphery of the display element area. This means the light intensity drops more gradually at the pixel edges, so that the abrupt pixel edges are less visible despite the magnification provided by a lens arrangement of the autostereoscopic display device.

Abstract: An autostereoscopic display device comprises a display arrangement such as an emissive display arrangement or an reflective display arrangement, with an array of spaced pixels. A light guiding arrangement has an array of light guide columns, with one column over each display pixel or over a group (such as a column) of pixels. The light guide columns comprise aside wall which tapers outwardly to define a funnel shape with the pixel at the smaller base of the funnel. The funnel provides collimation to reduce cross talk in the display, which is particularly problematic for 3D autostereoscopic displays.

Abstract: A light field display for providing continuous 3D images to viewers at multiple views is provided. The light field display includes a pixel layer having a plurality of pixel layer elements, a resonant subwavelength lens layer having a plurality of resonant subwavelength lenses and a circuit board connected to the pixel layer and the resonant subwavelength lens layer. Each resonant subwavelength lens in the resonant subwavelength lens layer is integrated with an element in the pixel layer. The element may be either a pixel or a subpixel, such that each image view may be provided per pixel or subpixel in the pixel layer.

Abstract: A multilayer display apparatus included in an in-vehicle system includes a stereoscopic vision display device formed by a 3D display unit and a 3D display control unit that display a three-dimensional image utilizing the principle of binocular disparity, a two-dimensional display device formed by a 2D display unit and a 2D display control unit that display a two-dimensional image on a two-dimensional display face, and a half-silvered mirror. The position of the two-dimensional display face is set within a predetermine range of the position of the screen of the stereoscopic vision display device by using the half-silvered mirror.

Abstract: The present invention relates to a dual-directional 3D image displaying method, being used in a case when a flat-panel display screen and a view separation device are used for dual-directional 3D image displaying, which comprises the steps of: using a display screen having a sub-pixel arrangement of 45-degree slant angle to display a multi-view 3D combined image; and using a view separation device featured by a 45-degree slant angle to perform a view separation operation upon the multi-view 3D combined image. Thereby, an object of dual-directional displaying of 3D images can be achieved using only one view separation device, without being bothered by conventional problems, such as cross-talk and color distortion.

Abstract: In an image display device having a parallax barrier element, a bright display with a broad viewing range can be realized. The image display device according to the present invention includes: a display panel having a first group of pixels for displaying a first image and a second group of pixels for displaying a second image; and a parallax barrier element for separating display light emitted from the first group of pixels and display light emitted from the second group of pixels, the parallax barrier element including a plurality of light-shielding portions and a plurality of light-transmitting portions which are alternately positioned within the same plane. The parallax barrier element includes converging elements respectively provided for the plurality of light-transmitting portions.

Abstract: A display panel includes a transmit-control portion and a light blocking portion. The pixel-transmit portion may include a pair of first sides and a pair of second sides and transmitting light, the pair of the first sides being inclined with respect to a horizontal-axis direction and substantially parallel with each other, the pair of the second sides being inclined with respect to a vertical-axis direction and substantially parallel with each other. The blocking portion may surround the pixel-transmit portion and block the light.

Abstract: A multi-layered micro lens sheet for a three-dimensional look includes a lens array layer in which first convex lenses and second convex lenses with different shapes are alternately arranged in longitudinal and transverse directions; a focal distance layer formed under the lens array layer; and a three-dimensional layer formed under the focal distance layer.

Abstract: A display apparatus includes a display panel, a light source part and a directional light projecting element. The display panel displays a first image during a first subframe and a different second image during a second subframe. The light source part provides light to the display panel. The directional light projecting element is disposed between the display panel and the light source part. The directional light projecting element includes a barrier part and a lens part disposed above the barrier part. The barrier part has a plurality of barriers defined as a plurality of first electrodes and a plurality of second electrodes crossing the first electrodes. The lens part has a plurality of lenses disposed in a first direction and a second direction crossing the first direction. Each of the lenses corresponds to a subset of plural lenses among the plurality of the barriers.

Abstract: Embodiments of the invention provide a color filter substrate, a fabrication method thereof, and a display device. The color filter substrate comprises: a substrate and a color filter film formed on a light incidence side of the substrate. At least one light refraction structure is continuously formed on a light incidence side of the color filter substrate, and each light refraction structure corresponds to a set of field of views (FOVs). The set of FOVs includes a left-eye FOV and a right-eye FOV, light rays from the left-eye FOV pass through a portion of the light refraction structure to which the left-eye FOV corresponds into a left-eye view zone, and light rays from the right-eye FOV pass through the other portion of the light refraction structure to which the right-eye FOV corresponds into a right-eye view zone.

Abstract: There is provided a lenticular sheet including: a lenticular lens having a plurality of convex lens parts arranged two-dimensionally; a first ink absorbing layer which is provided on a surface, of the lenticular lens, opposite the convex lens parts and in which ink permeates; a suppressing part provided on the first ink absorbing layer to divide the first ink absorbing layer into a plurality of regions and suppressing the ink from permeating across the plurality of the regions; and a second ink absorbing layer provided to cover the suppressing part.

Abstract: Optical films used for 3D autostereoscopic displays include lenses on one surface of the optical film that are registered to prisms on the opposing surface of the optical film. The lenses may be a-cylindrical lenses or cylindrical, and the rotation of the lenses can vary with position on the surface of the optical film. The prisms may be contiguous or non-contiguous. The prisms of the optical film can have a pitch that is different from a pitch of the lenses, or the prism pitch can be substantially the same as the pitch of the lenses.

Abstract: An optical system comprising a circular image strip comprising an inner image strip, an outer image strip, and an effective zone, and a circular lenticule configured to direct light reflected from the inner image strip to a first eye of a viewer and to direct light reflected from the outer image strip to a second eye of a viewer when the viewer views an effective zone of the circular image strip is disclosed.

Abstract: A rear parallax emitter is disclosed for use, for example, in a display. The display includes a light modulator as well as the rear parallax emitter. The light modulator comprises a plurality of pixels viewable at a viewing position. The rear parallax emitter comprises a plurality of sets of light emitting regions (LERs) and has an area substantially coextensive with the light modulator and spaced a prescribed uniform distance from the display opposite from a viewing position. Each set of LERs is independently controllable to transmit a light color that differs from a light color transmitted by another set of LERs.

Abstract: A lens array sheet has a glass base and a resin lens array layer formed on the glass base, wherein the resin lens array layer includes a plurality of resin lenses and preferably includes a composite material having nanoparticles added to a matrix of the resin and the plurality of resin lenses are formed on the glass base substantially independently from each other.

Abstract: This invention describes a method of stereoscopic printing and its application in decorative plate and light box. The stereoscopic printing method includes a substrate with concave and convex surface micro structures followed by printing with electron beam or UV light curable ink to retain the surface morphology after printing. The printing resolution is between 5 and 20 times the density of concave and convex surface structure to create the decorative plate with visual depth perception. If the micro structured substrate is transparent, a high contrast image on a decorative plate or a light box can be obtained by integration of a reflective film or a back light unit.

Abstract: A marker for lens is provided as aligning unit in a lenticular lens of an optical unit, and a marker for display panel is provided as aligning unit in a transmissive liquid crystal display panel of the display panel. A fixing unit is provided in at least a part of an area that encloses an image display area of the lenticular lens. An image display device is formed in such a manner that alignment between the lenticular lens and the liquid crystal display panel is performed by the marker for lens and the marker for display panel and the lenticular lens is fixed to a surface of the liquid crystal display panel on the side of a viewer.

Abstract: A multi-view autostereoscopic display device comprises: a backlight having a plurality of backlight areas arranged in a width direction of the display device; a spatial light modulator arranged over and in registration with the backlight, the spatial light modulator having an array of display forming elements arranged in rows and columns for modulating light received from the backlight; and a view forming layer arranged over and in registration with the spatial light modulator, the view forming layer having a plurality of view forming elements arranged in the width direction of the display device, each view forming element being configured to focus modulated light from adjacent groups of the display forming elements into a plurality of views for projection towards a user in different directions.