A steerable laser transmitter pairs a MEMS MMA with an optical amplifier to provide a high-power steered laser beam over a wide FOR. A single MEMS MMA may be positioned downstream of the optical amplifier. In a two-stage architecture, a MEMS MMA provides continuous fine steer upstream of the optical amplifier and a beam steerer, another MEMS MMA or a QWP and stack of switchable PGs, provides discrete coarse steering downstream. In the two-stage architecture, the upstream MEMS MMA is configured to limit its steering range to the acceptance angle of the optical amplifier, at most ±2°×±2°. The MEMS MMA may include piston capability to shape the wavefront of the beam.

The color filter substrate includes a photoluminescent layer and an optical path adjustment layer. The photoluminescent layer includes a plurality of photoluminescent portions. Each photoluminescent portion is configured to receive backlight and emit excitation light. The optical path adjustment layer is located on a light incident side of the photoluminescent layer, and the optical path adjustment layer is configured to increase an incident angle of at least portion of the backlight that enters the photoluminescent layer.

A display device comprising a display module configured to define a display surface. The display module includes a display panel including a plurality of display elements configured to display an image on the display surface. A plurality of diffraction patterns are spaced apart on the display panel at a constant interval. The diffraction patterns are configured to diffract at least some light beams emitted from the plurality of display elements. The plurality of diffraction patterns comprise an organic material.

An optical assembly may include a waveguide and a Bragg grating configured to couple light into or out of the waveguide. The Bragg grating may include a plurality of layer pairs, wherein at least one layer pair comprises a first material having a first refractive index and a second layer having a second refractive index, and wherein properties of the Bragg grating are selected so that the Bragg grating exhibits a substantially similar diffractive efficiency and diffraction angle for light of at least two colors.

The disclosure provides an optical waveguide system and a near-eye display. An optical waveguide system includes: an optical waveguide; an in-coupling grating, arranged on one side surface of the optical waveguide, the in-coupling grating is a one-dimensional grating, and is configured for coupling light emitted by a micro-projector located externally into the optical waveguide; a turning grating, arranged on the optical waveguide and is located on the same side surface or a different side surface of the in-coupling grating, the turning grating is a two-dimensional grating, and is configured for receiving light of the in-coupling grating; and an out-coupling grating, arranged on the other side surface of the optical waveguide, projections of the turning grating and the out-coupling grating on the optical waveguide at least partially coincide, the out-coupling grating is a one-dimensional grating.

A method of forming a plurality of gratings for an optical device structure are provided. The method utilizes a high refractive index material and a metallic coating.

A display element according to an embodiment of the present technology includes an optical control layer and a lens layer. The optical control layer modulates incident light for each pixel. The lens layer includes an incident surface, a plurality of refractive lenses disposed for each pixel, and a plurality of diffractive lenses disposed for each pixel to face the plurality of refractive lenses, and emits light incident from the incident surface and passing through the plurality of refractive lenses and the plurality of diffractive lenses to the optical control layer.

A display device is provided. The display device includes a backlight module with a reverse prism structure disposed on top, and a display module disposed above the backlight module. The display module includes a display panel and a sensor component. The sensor component is embedded in the display panel. The sensor component includes a plurality of sensors. A plurality of diffraction gratings are disposed on surfaces of the plurality of sensors. A grating direction of the plurality of diffraction gratings is perpendicular to a grating direction of the reverse prism structure.

A security element including: a first layer having a first surface; an array of image regions across the surface, each region including at least first and second sub-regions; a first diffractive optically variable effect generating structure in or on the surface across the first sub-regions; and a second diffractive optically variable effect generating structure in or on the surface across the second sub-regions; wherein the surface is arranged so each first sub-region has a first average inclination and each second sub-region has a second average inclination different from the first, wherein the first structure and inclination provide that the first effect is exhibited across the first sub-regions at least at a first viewing angle and the second structure and inclination provide that the second effect is exhibited across the second sub-regions at least at a second viewing angle different from the first. Also, a method of manufacturing the security element.

An optical waveguide combiner includes an optical waveguide substrate and an optical input region. The optical input region includes an optical input diffractive grating integrated in, or disposed on, the optical waveguide substrate. An optical output region includes an optical output diffractive grating integrated in, or disposed on, the optical waveguide substrate, At least one non-diffractive region includes at least one optical non-diffractive array of nanostructures, wherein said at least one optical non-diffractive array of nanostructures is integrated in, or disposed on, the object side of said optical waveguide substrate and at least partially surrounds at least said optical output grating; wherein the external visible reflectance of said at least one non-diffractive array of nanostructures is substantially equal to the external visible reflectance of said optical output grating.