The invention relates in particular to a method for creating patterns in a layer (410) to be etched, starting from a stack comprising at least the layer (410) to be etched and a masking, layer (420) on top of the layer (410) to be etched, the masking layer (420) having at least one pattern (421), the method comprising at least; a) a step of modifying at least one zone (411) of the layer (410) to be etched via ion implantation (430) vertically in line with said at least one pattern (421); b) at least one sequence of steps comprising: b1) a step of enlarging (440) the at least one pattern (421) in a plane in which the layer (410) to be etched mainly extends; b2) a step of modifying at least one zone (411″, 411″) of the layer (410) to be etched via ion implantation (430) vertically in line with the at least one enlarged pattern (421), the implantation being carried out over a depth less than the implantation depth of the preceding, modification step;) c) a step of removing (461, 462) the modified zones (411, 411′, 41″), the removal comprising a step of etching the modified zones (411, 411′, 411″) selectively with respect to the non-modified zones (412) of the layer (410) to be etched.

A beam intensity uniformizing element includes an optical base, a first lens array disposed at a front surface of the optical base; and a second lens array disposed at a back surface of the optical base. The first lens array includes first mold lens cells arranged in different directions along the front surface of the optical base. The first mold lens cells have surfaces constituting the front surface of the optical base. The surfaces of the first mold lens cells have first linear marks thereon extending in a first direction. The second lens array includes second mold lens cells arranged in different directions along the back surface of the optical base. The second mold lens cells have surfaces constituting the back surface of the optical base. The surfaces of the second mold lens cells have second linear marks thereon extending in a second direction different from the first direction. This element suppresses generation of an interference pattern and reduces cost.

A method for manufacturing a roll mold by cutting a roll, includes generating a control waveform based on a signal corresponding to a rotary position of the roll, and making a plurality of cuts on a surface of the roll by, while the roll is rotated, reciprocating a cutting blade in a radial direction of the roll in accordance with the control waveform. Making the plurality of cuts includes at each of a plurality of predetermined locations, making a predetermined number of cuts of predetermined depth based on the control waveform. Generating the control waveform includes generating a control waveform dictating that the predetermined locations, the predetermined depths, or both are randomly selected. Generating the control waveform includes generating a control waveform dictating that, when multiple cuts are made at a predetermined location, each subsequent cut will have a smaller depth than a preceding cut.

An optical lens device includes an optical substrate layer, an etched miniature-structure polarization layer and an etched miniature surface structure. The optical substrate layer is provided with a first surface and a second surface and a ray of light passes through the optical substrate layer. The etched miniature-structure polarization layer is provided on the first surface or the second surface of the optical substrate layer. The etched miniature surface structure is etched to form the miniature-structure etched polarization layer and provides a characteristic of optical polarization in the etched miniature-structure polarization layer. The etched miniature surface structure of the etched miniature-structure polarization layer provides an effect of optical polarization to the ray of light while passing through it.

The optical device includes: a beam radiation unit configured to radiate light; a first aspheric lens unit including a first focal point, the first aspheric lens positioned on a light output side of the beam radiation unit such that the first focal point is formed at a light output surface of the beam radiation unit on the light output side of the beam radiation unit; and second aspheric lens units including second focal points, the second aspheric lens units positioned on the light output side of the beam radiation unit such that the second focal points are formed to overlap the first focus at the light output surface of the beam radiation unit.

According to an embodiment of the disclosure, an electronic device may include a housing including a rear plate including a first region having a first concavo-convex pattern formed therein, and a second region having a second concavo-convex pattern formed therein, and a processor disposed inside the housing. The first concavo-convex pattern and the second concavo-convex pattern may be integrally formed with the rear plate, and a first depth of the first concavo-convex pattern may be different from a second depth of the second concavo-convex pattern.

An inverted nanocone structure of the present disclosure includes a first surface, a second surface spaced apart from the first surface by a predetermined distance and having a greater area than the first surface, and a body having an inverted cone shape between the first surface and the second surface, wherein at least one activated point defect center is provided in the body.

A high-performance optical surface includes: a substrate having a first surface and a second surface opposite to the first surface; a first anti-reflection (A/R) coating formed on the second surface of the substrate; a coated layer formed over the A/R coating on a surface of the A/R coating opposite to the stress compensation layer, where a surface of the coating layer opposite to the first A/R coating is diamond point turned or polished to improve finish; and a second A/R coating formed on the polished surface of the coating layer to formed the high-performance reflective surface.

Disclosed is a method implemented by a computer for determining surfacing data to obtain a surface of a lens element, the surface of the lens element including: a refraction area having a first curvature; and multiple optical elements placed on at least part of the finished optical surface, each optical element having at least a second curvature.

A rod lens array unit includes at least a rod lens array that includes a plurality of rod lenses arranged in a line, each of the rod lenses having an optical axis extending in an optical axis direction, and a pair of side plate parts stacked so as to sandwich the rod lens array. Wherein, end faces of the side plate parts in the optical axis direction of the rod lens array are positioned inside an end face of the rod lens array in the optical axis direction.