A focusing device includes a substrate and a plurality of scatterers provided at both sides of the substrate. The scatterers on the both sides of the focusing device may correct geometric aberration, and thus, a field of view (FOV) of the focusing device may be widened.

A color developing structure that exhibits good color development and ensures a desired transmittance while diffusing reflected light in multiple directions. A color developing structure includes a concave-convex layer in which a first surface has a concave-convex structure, and a reflective layer formed on the first surface to extend along the concave-convex structure. A convex surface of the concave-convex structure has a first pattern composed of a plurality of strip portions in plan view. The strip portion has a width in a first direction and a length in a second direction perpendicular to the first direction. The width is smaller than the wavelength of the incident light, and a standard deviation of the lengths of the plurality of strip portions is larger than a standard deviation of the widths.

Examples include a device including a nanovoided polymer element having a first surface and a second surface, a first plurality of electrodes disposed on the first surface, a second plurality of electrodes disposed on the second surface, and a control circuit configured to apply an electrical potential between one or more of the first plurality of electrodes and one or more of the second plurality of electrodes to induce a physical deformation of the nanovoided polymer element.

There is provided a method that includes depositing a plurality of layers in a substrate including a pattern. The plurality of layers can form a stack that includes at least two different materials. The stack thus forms a composite layer which has an effective index of refraction that is unique. The method may make use of at least two different materials, which can be a combination of aluminum oxide (A12O3), Titanium Dioxide (TiO2), and silicon dioxide (SiO2). These materials may be deposited via atomic layer deposition (ALD).

A resonant waveguide grating includes a waveguiding layer and a plurality of subwavelength structures. The waveguiding layer, being in optical proximity to the plurality of subwavelength structures, is configured to guide at most ten wave-guided light modes. The plurality of subwavelength structures includes at least two adjacent grooves having a subwavelength distance between their groove centers being different than the subwavelength distance between the centers of two adjacent ridges. The plurality of subwavelength structures is configured to couple out of the waveguiding layer resonantly by diffraction, an outcoupled fraction of an incoupled portion of incident light. The outcoupled fraction is a diffracted part of an incident light beam. A diffractive optical combiner and a diffractive optical coupler, both include the resonant waveguide grating of the invention. A near-eye display apparatus includes at least the resonant waveguide grating of the invention.

A metallic grating is formed to include a substrate; a plurality of high aspect ratio trenches disposed in the substrate such that the high aspect ratio trenches are spaced apart from one another by a field surface of the substrate; a metallic superconformal filling formed and disposed in the high aspect ratio trenches; and a grating including a spatial arrangement of the high aspect ratio trenches that are filled with the metallic superconformal filling such that the metallic superconformal filling is void-free, and the high aspect ratio trenches are bottom-up filled with the metallic superconformal filling, wherein a height of the metallic superconformal filling is less than or equal to the height of the high aspect ratio trenches.

An eyewear apparatus is disclosed which comprises at least one light display engine (LDE) configured to generate at least one image on a display (disp1) of said light display engine, a waveguide (WG) configured for guiding light from the light display engine towards an eye of a user to make said image (Im1) visible to the user, wherein said display (disp1) is shifted (d) on one side with respect to an optical axis of said light display engine such that said image (Im1) is visible to the user on a corresponding side of a field of view (HFoV) of said eyewear apparatus.

A method includes providing a coating over a surface of a substrate, a plurality of seed structures being disposed on the surface of the substrate, in which respective heights of the seed structures define local thicknesses of the coating. An optical device includes a substrate, a plurality of seed structures on a surface of the substrate, and a coating on the seed structures and on the surface of the substrate, in which respective heights of the seed structures define local thicknesses of the coating.

A diffraction grating includes a plurality of grating unit cells positioned in a periodic array on a substrate surface. In cross-section, a grating unit cell includes a homogeneous dielectric host medium with a first refractive index n.sub.1, embedding at least a first block of a first dielectric material with a second refractive index n.sub.2, a side edge of which is in direct contact with at least a second block of a second dielectric material with a third refractive index n.sub.3. Both the first block and the second block have a trapezoidal cross-section. The plurality of grating unit cells provides a non-symmetrical response for positive first diffraction order and negative first diffraction order based on nanojet hot spot positions, the nanojets being generated at edges between dielectric materials with different refractive indexes.

The present disclosure relates to method, computer programs with instructions, and apparatus for determining positions of two or more spaced-apart molecules in one or more spatial directions in a sample by means of a localization microscope. The present disclosure also relates to localization microscopes using such an apparatus. Light distributions arising due to interference of coherent light are used for determining the positions of the molecules. In the method, a plurality of light distributions are generated (S1) using a first light modulator having a plurality of switchable pixels. The first light modulator is arranged in an image plane of the localization microscope. Each light distribution has a local intensity minimum and regions with an intensity increase adjacent thereto. Each of the two or more molecules is illuminated (S2) with one light distribution. For each of the light distributions, photons emitted by the molecules are detected (S4) for different positionings of the light distribution. The light distributions are positioned (S3) independently of each other. Based on the photons detected for the different positionings of the light distributions, the positions of the molecules are finally derived (S5).