A LIDAR sensor, which includes a transmitting unit and a deflection unit. The transmitting unit is configured to generate a laser beam, whose local beam distribution includes a double peak distribution along a deflection direction of the deflection unit. The light energy of which in a central section between the two peaks is less by a predefined factor than the light energy in sections in each case laterally adjacent thereto, which include the peaks. The deflection unit is configured to deflect the laser beam generated by the transmitting unit along the deflection direction into surroundings of the LIDAR sensor.

A multiview backlight and display employ diffusion of directional light beams to provide an image of color regions of a color-tailored multibeam element having a size comparable to a size of the color-tailored multibeam element. The multiview backlight includes an array of color-tailored multibeam elements configured to provide the directional light beams and an optical diffuser configured to spread out directional light beams to provide the color region image. The multiview display includes an array of the color-tailored multibeam elements and the optical diffuser. The multiview display further includes an array of light valves configured to modulate the directional light beams as a multiview image.

There is provided a microlens array diffuser plate including: a microlens group positioned on a surface of a transparent substrate. The microlens group at least corresponding to a light ray entering part in the microlens array diffuser plate includes two or more unit cells that are continuous in an array sequence, and the unit cells include a plurality of microlenses positioned on the surface of the transparent substrate. The light ray entering part has at least two regions having different average diffusion angles.

A backlit transparent display and a transparent display system provide a displayed image while enabling a background scene to be visible through the display. The backlit transparent display includes a light guide, a plurality of scattering elements, and an array of light valves configured to modulate emitted light scattered from the light guide to provide modulated emitted light representing a displayed image. Transparency of the backlit transparent display is configured to enable the background scene to be visible through the backlit transparent display. The transparent display system includes the array of light valves and a transparent backlight. The transparent display system is configured to provide the displayed image as superimposed on the background scene visible through the transparent display system.

An optical element is configured to be worn in front of an eye of a wearer. The optical element has two main surfaces and includes at least one holographic diffusive element having diffusive properties resulting from spatial variations of refractive index of said holographic diffusive element. The spatial variation of refractive index is greater than 0.001 at at least one given wavelength, on a distance less than 30 μm. An optical equipment includes the optical element and methods for recording a holographic medium onto an optical lens.

A diffusion element is configured by combining: a structure for diffusion constituted by combining periodic surface structures having multiple periods to achieve a light intensity distribution in which the light intensity is uniform at angles less than or equal to a predetermined diffusion angle θ and the light intensity is as close as possible to zero intensity at angles greater than the diffusion angle θ; and a diffractive structure having a period of 1 or more and 2 or less times of Λmax, where Λmax is the maximum period of the structure for diffusion.

A coherent beam moves across a stationary line generator, allowing the speckle pattern projected through the diffuser onto the surface—for example using a MEMS mirror, or another arrangement that is free of a moving mass, such as solid state beam deflector (e.g. an AOM). Where an image sensor is employed, such as a DS, the beam is moved at a speed of at least ½ cycle per image frame so that the full length of the line within the imaged scene is captured by the image sensor. The distance traversed on the diffuser provides sufficient uncorrelated speckle patterns within an exposure time to average to a smooth line. The MEMS mirror can be arranged to oscillate in two substantially orthogonal degrees of freedom so that the line is generated along a first direction and the line moves along the working surface in a second direction.

The present disclosure provides a backlight module, a liquid crystal display, and an electronic device. The backlight module includes: a backplane; at least one light source arranged on the backplane; and at least one diffractive optical element arranged above the light source, and a central axis of the diffractive optical element and a central axis of the light source are on a same straight line.

Techniques disclosed herein relate to modifying refractive index modulation in a holographic optical element, such as a holographic grating. According to certain embodiments, a holographic optical element or apodized grating includes a polymer layer comprising a first region characterized by a first refractive index and a second region characterized by a second refractive index. The holographic optical element or apodized grating includes a plurality of nanoparticles dispersed in the polymer layer. The nanoparticles have a higher concentration in either the first region or the second region. In some embodiments, the nanoparticles may be configured to increase the refractive index modulation. In some embodiments, the nanoparticles may be configured to apodize the grating by decreasing the refractive index modulation proximate to sides of the grating. The refractive index may be modulated by applying a monomer reservoir buffer layer to the polymer layer, either before or after hologram fabrication.

An optical device for a motorcar capable of generating three-dimensional optical and/or visual effects. The optical device comprises: a plurality of light sources, each one adapted to emit a light beam in a predetermined direction; a supporting element whereon the light sources are mechanically and electrically connected; and at least one optical module, which is adapted to be crossed by a light beam to emit light presenting a three-dimensional optical effect. The plurality of light sources include a plurality of micro-LEDs. The optical module include at least one layer of diffractive material. The optical module is arranged substantially parallel to the supporting element whereon the micro-LEDs lie. The optical module is arranged substantially perpendicular to the light beams emitted by the micro-LEDs.