An optionally transferable optical system with a reduced thickness is provided. The inventive optical system is basically made up of a synthetic image presentation system in which one or more arrangements of structured image icons are substantially in contact with, but not completely embedded within, one or more arrangements of focusing elements. The focusing element and image icon arrangements cooperate to form at least one synthetic image. By way of the subject invention, the requirement for an optical spacer to provide the necessary focal distance between the focusing elements and their associated image icon(s) is removed. As a result, overall system thicknesses are reduced, suitability as a surface-applied authentication system is enabled, and tamper resistance is improved.

The invention relates to a method for producing a thin and substantially fracture-resistant display device comprising a display, wherein an upper layer having a surface facing an observer is arranged on light-emitting luminous surfaces of the display, wherein micro-passages for transmitting generated light from the light-emitting luminous surfaces of the display are formed in the upper layer and form micro-openings in the surface facing an observer, wherein a substantially planar surface facing the observer is created on the upper layer, and wherein creating the substantially planar surface comprises processing the surface of the display device facing the observer by means of a laser and/or by means of machining in order to produce the substantially planar surface. Furthermore, the invention relates to a display device.

An imaging device may include one or more photosensitive regions in a pixel formed as part of an image pixel array. Microlenses and color filter structures may be formed over the pixel. Each microlens may be formed from a microlens seed and one or more deposition microlens layers formed over the microlens seed. The deposition microlens layer(s) as deposited may already define the curvature of the microlens. As such, no further etching or smoothing process is need for the microlens layer(s) formed over the microlens seed. If desired, the microlens seed may have a planar top surface and planar sides, a planar top surface and slanted planar sides, or a nonplanar top surface and planar sides. The microlens seed may define microlens characteristics of the microlens such as the radius of curvature, the height, and/or the number and type of microlens lobes.

An optical element, a mobile phone cover plate provided with the optical element, and a mold for manufacturing the optical element. The optical element comprising at least two types of arranged optical units, the optical units comprising optical structures producing light shadow effects; wherein a light shadow effect produced by an optical structure of one type of optical units is different from a light shadow effect produced by an optical structure of another type of optical units. The optical units are arranged and there are at least two types of different optical units, the optical structures there of being able to produce different light shadow effects, so that the optical element has a good visual effect, and when it is applied in the field of decoration, it is able to enhance a decoration effect, and make the decoration rich in visual senses and pictures vivid.

This application discloses an optical sheet, including a polymer layer; a certain number of small short lines, the certain number of small short lines being formed at a side of the polymer layer and forming a micro-nano structure; wherein at least one of the small short lines is of a convex structure or a concave structure, and two sidelines of the small short line are parallel to each other or intersect in a plane. This application provides a new texture structure, in which directions of the small short lines may be changed randomly or according to a wanted effect in a certain direction. There exists at least one light pillar in the optical sheet with such a texture structure under a certain light source. The cover plate for an electronic device adopts the texture structure or the optical sheet.

The invention relates to a method for producing a thin and substantially fracture-resistant display device comprising a display, wherein an upper layer having a surface facing an observer is arranged on light-emitting luminous surfaces of the display, wherein micro-passages for transmitting generated light from the light-emitting luminous surfaces of the display are formed in the upper layer and form micro-openings in the surface facing an observer, wherein a substantially planar surface facing the observer is created on the upper layer, and wherein creating the substantially planar surface comprises processing the surface of the display device facing the observer by means of a laser and/or by means of machining in order to produce the substantially planar surface. Furthermore, the invention relates to a display device.

A production method includes fixing ball elements of a semiconductor material to a carrier substrate by means of heat and pressure; and one-sided thinning of the ball elements fixed to the carrier substrate to form plano-convex lens elements of a semiconductor material.

This invention discloses a method of forming an uneven structure on a substrate. Use a hard tool to penetrate into a mold to cut a first trench and a second trench in an order on a surface of a mold, wherein the hard tool has a smoothly-curved shape such that the transverse width of each of the first trench and the second trench increases as the penetrating depth of the hard tool increases, wherein when each of the first trench and the second trench marches along a first direction, the penetrating depth of the hard tool is controlled by repeating moving the hard tool up and down to cut the mold such that the transverse width of each of the first trench and the second trench varies according to the controlled penetrating depth of the hard tool, wherein the first trench and the second trench completely overlap with each other with no space therebetween. Then, use the surface of the mold to emboss a thin film on a substrate.

An optical device includes an optical module, a lens, and a first adhesive member. The optical module includes a base seat, a frame member that defines a hollow region and that has a top surface, and an optical element that is connected to the base seat and that is received in the hollow region. The lens has a first surface that faces the base seat and the optical element, and that is connected to the frame member to cover the hollow region, a second surface that is opposite to the first surface, and a side surface that interconnects the first and second surfaces. The first adhesive member is connected to the side surface of the lens and the top surface of the frame member. A method for manufacturing optical devices is also disclosed.

The present invention relates to a micropattern layer based image film and a method for manufacturing the same. The image film comprises: a sacrificial layer; a first micropattern layer formed on the sacrificial layer; a second micropattern layer formed on the first micropattern layer; a focal length layer formed on the second micropattern layer; and a micro-image pattern formed on the focal length layer, wherein the first micropattern layer includes a plurality of concave parts extending in one direction, and concave curved surfaces of the plurality of concave parts are formed adjacent to the sacrificial layer; the second micropattern layer includes a plurality of convex parts extending in one direction, and convex curved surfaces of the plurality of convex parts are formed adjacent to the focal length layer; and the first micropattern layer and the second micropattern layer are orthogonal to each other.