A liquid crystal cell and a photographic system are described. The liquid crystal cell includes: a refractive index switching layer including a liquid crystal layer consisting of liquid crystals and a substrate on which a plurality of diffractive lenses are formed; a first transparent electrode layer; and a second transparent electrode layer. The liquid crystal layer has a first refractive index and a second refractive index when the first transparent electrode layer and the second transparent electrode layer are powered on and off, respectively. The first refractive index is greater than the second refractive index, and the first refractive index is the same as the refractive index of the diffractive lenses. By means of this solution, free and controllable switching between light field imaging and conventional photographic imaging can be realized in the same system.

A transparent substrate having an antiglare surface with reduced display sparkle. The transparent substrate has a roughened antiglare surface and a diffraction element below the antiglare surface. The diffraction element reduces sparkle by filling gaps between sub-pixels in a pixelated display with orders of diffraction. A display system comprising the transparent substrate and a pixelated display is also provided.

A light field generation system includes a two dimensional emitter array for projecting light and a directionally-sensitive optical element in front of the emitter array but before a directional diffuser. Certain classes of emitters are intended to project information principally along one axis (e.g. amplitude modulated in the horizontal plane, i.e. so that each eye sees a potentially different image) and are the basis of horizontal-parallax-only (HPO) displays. Examples include surface acoustic wave (SAW) modulators, such as edge-emitting or surface-emitting modulators. They often project undesired or stray light along directions along a different axis (e.g. vertically) and the diffuser will also spread the visibility of the stray light field components. Thus, the directionally-sensitive optical element will improve contrast in this scenario.

The invention provides an autostereoscopic display device having an adjuster for adjusting the direction of a light beam (5). The adjuster (1) has an off-state and on-state and comprises a stack (10) of layers. The stack (10) comprises a first solid material layer (100) having a first optic axis (111), a second solid material layer (200) having a second optic axis (211), and switchable birefringent twisted nematic liquid crystal material (30) or chiral nematic liquid crystal material. Further, the stack includes a first interface (130) between the first solid material layer (100) and birefringent material (30) and a second interface (230) between the second solid material layer (200) and birefringent material (30). In the off-state, the birefringent material (30) at the first interface (130) is configured to have an optic axis parallel to the first optic axis (111) and the birefringent material (30) at the second interface (230) is configured to have an optic axis parallel to the second optic axis (211). In the on-state, the birefringent material (30) at the first interface (130) is configured to have an optic axis perpendicular to the first optic axis (111) and the birefringent material (30) at the second interface (230) is configured to have an optic axis perpendicular to the second optic axis (211).

An image displacement device includes a first grating and a second grating. Each grating is switchable between a diffracting state and a non-diffracting state. The first grating has a first surface and a second surface opposite the first surface, the first surface receives image beams, and the image beams leave the first grating by the second surface. The second grating is disposed downstream from the first grating in a light path and has a third surface and a fourth surface opposite the third surface. The third surface receives the image beams, and the image beams leave the second grating by the fourth surface. An exit direction of the image beam exiting the second grating is shifted a distance in a first direction from an incident direction of the image beam incident to the first grating.

An acousto-optic device capable of increasing a range of a diffraction angle of output light by using a nanostructured acousto-optic medium, and an optical scanner, an optical modulator, a two-dimensional/three-dimensional (2D/3D) conversion stereoscopic image display apparatus, and a holographic display apparatus using the acousto-optic device. The acousto-optic device may include a nanostructured acousto-optic medium formed by at least two different mediums repeatedly alternating with each other, wherein at least one of the at least two different mediums includes an acousto-optic medium. The acousto-optic device having the aforementioned structure may increase the range of a diffraction angle of output light. Thus, various systems such as the optical scanner, the optical modulator, the 2D/3D conversion stereoscopic image display apparatus, and the holographic display apparatus may not require a separate optical system to increase an operational angle range, thereby decreasing a size of the system and/or improving a resolution of the system.

One embodiment of the invention provides a pattern generation device includes a light source, a first HPDLC cell, and a second HPDLC cell. The first HPDLC cell is disposed downstream of a light path of the light source and contains a first phase modulation pattern. The second HPDLC cell is disposed downstream of a light path of the first HPDLC cell and contains a second phase modulation pattern.

A projector includes a beam homogenizer receiving light from a light source and creating a predetermined illumination, and a spatial light modulator including grating stages to receive the predetermined illumination. Each grating stage may include a plurality of pixels where corresponding pixels in the grating stages are aligned with one another. Each of the pixels may include a liquid crystal layer disposed between two substrates, where a pixel is switchable by applying a voltage thereto, with a grating period of the pixel selected such that, when the voltage is applied to the pixel and light is passed therethrough, optical energy from the light in plus and minus first orders is deflected toward sides of the pixel and optical energy from a zero order of the light is allowed to pass through the pixel, with a polarization state of the light maintained through the pixel.

The technology disclosed relates to developing an acousto-optic device (AOD) using an alpha-barium borate (BBO) crystal. An AOD using BBO enables high-resolution microlithographic patterning. The AOD includes a slab of BBO coupled to an RF transducer that drives an acoustic wave through the crystal structure. A laser source emits a beam of light that is incident on the crystal surface. The propagated acoustic wave acts as a diffraction grating that diffracts the incident wave. Using an BBO crystal allows for high resolution of light in the ultraviolet and visible spectra. The low speed of acoustic wave propagation through the crystal allows for more laser spots to be imaged than AODs made using other types of crystals.

There can be a problem of output intensity node or nodes as a function of angle, for waveguide-based optical modulators, such as leaky-mode surface acoustic wave modulators. Several approaches are illustrated that can be used to provide more uniform output light across a range of angles, i.e., that is avoid dark drop-outs. It can also be used to increase the output angle range or exit light fan. This is achieved by leveraging the different diffraction characteristics between different guided modes. It exploits the observation that utilizing different waveguide guided modes, e.g. TE0 like versus TE1-like, causes a SAW optical modulator to operate with different relationships between output angle and output intensity. It turns out that they can be at least complementary, that is: one waveguide mode can fill in the dark gaps of another wave guide mode.