An optical device includes a refractive prism including a first surface facing an object, a second surface facing a first lens, and a third surface configured to reflect incident light to change a path of the incident light, one of the first surface, the second surface, or both the first and the second surface includes a pattern such that the refractive prism is a diffractive optical element; and a plurality of lenses including the first lens.

A diffractive multifocal lens is disclosed, comprising an optical element having at least one diffractive surface, the surface profile comprising a plurality of annular concentric zones. The optical thickness of the surface profile changes monotonically with radius within each zone, while a distinct step in optical thickness at the junction between adjacent zones defines a step height. The step heights for respective zones may differ from one zone to another periodically so as to tailor diffraction order efficiencies of the optical element, in one example of a trifocal lens, step heights alternate between two values, the even-numbered step heights being lower than the odd-numbered step heights. By plotting a topographical representation of the diffraction efficiencies resulting from such a surface profile, step heights may be optimized to direct a desired level of light power into the diffraction orders corresponding to near, intermediate, and distance vision, thereby optimizing the performance of the multifocal lens.

A diffractive optical element includes: a first material layer that has a diffractive grating shape; and a second material layer that is laminated on the first material layer, the diffractive grating shape forming a plurality of concentric annular ring zones in a plan view from a lamination direction of the first material layer and the second material layer, and a radius of an innermost first ring zone among the plurality of ring zones is less than any one of distances between the ring zones.

Provided are methods for geometric intrinsic camera calibration using a diffractive optical element. Some methods described include receiving, by at least one processor, at least one image captured by a camera based on a plurality of light beams received from a diffractive optical element aligned with an optical axis of the camera, the plurality of light beams having a plurality of propagation directions associated with a plurality of view angles. The at least one processor identifies a plurality of shapes in the image, determines a correspondence between the plurality of shapes in the image and the plurality of light beams, and identifies one or more intrinsic parameters of the camera that minimize a reprojection error function based on the plurality of shapes in the image and the plurality of propagation directions. Systems and computer program products are also provided.

Provided is an augmented reality display with a thin optical combiner, and the augmented reality display with a thin optical combiner provided to have an overall shape wearable by a user includes an optical combiner part provided in the form of a lens located in front of a user's eyes to receive a virtual image light wave and combine an external scene and a virtual image, wherein the optical combiner part includes a plurality of glass substrates, and a polarization-dependent lens inserted obliquely in a diagonal direction between the plurality of glass substrates to transmit optically modulated virtual image light waves in a direction toward the eyes.

Provided are an optical element and an image display apparatus that display an aerial image, in which the total volume of the apparatus is small, a reduction in size can realized, and a scenery can be recognized. The optical element includes: a light guide element including a light guide plate, an incidence diffraction element, and an emission diffraction element, the incidence diffraction element being disposed on a main surface of the light guide plate and the emission diffraction element being disposed on the main surface of the light guide plate; and a reflection lens that is disposed at a position overlapping the emission diffraction element in a view from a direction perpendicular to the main surface of the light guide plate, in which the incidence diffraction element diffracts incident light such that the diffracted light is incident into the light guide plate, the emission diffraction element emits light propagating in the light guide plate from the light guide plate, and the reflection lens collects the light that is emitted from the light guide plate by the emission diffraction element.

A label, and methods and systems for preparing the label. The label includes a lens or lens array. The label includes at least one surface, a portion of which is embossed, and a lens array provided by the embossed portion of the at least one surface. The method includes applying a material to a substrate and contacting a surface of the material with a master engraving to provide an embossed region on a least a portion of the surface of the material, wherein the embossed region provides at least one lens.

An optical device is provided. The optical device has a central region and a first-type region surrounding the central region. The first-type region includes a first sub-region and a second sub-region between the central region and the first sub-region. The optical device includes a substrate. The optical device also includes a meta-structure disposed on the substrate. The meta-structure includes first pillars in the first sub-region and second pillars in the second sub-region. In the cross-sectional view of the optical device along the radial direction of the optical device, two adjacent first pillars have a first pitch, two adjacent second pillars have a second pitch, and the second pitch is greater than the first pitch.

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 meta-optical device and a method of manufacturing a metasurface are provided. The meta-optical device includes a substrate and a nanostructure, wherein the nanostructure includes a first portion and a second portion that differ in at least one of a diameter and a period, wherein a ratio of an etch depth of the second portion to an etch depth of the first portion is about 0.9 to about 1.1, and the nanostructure includes at least one of sulfur, fluorine, and fluorocarbon.