Provided is a curable composition capable of giving a lens that has excellent transfer accuracy from a mold and offers heat resistance and optical properties at excellent levels. The curable composition according to the present invention for lens formation contains a cycloaliphatic epoxide (A) represented by Formula (a), a cationic-polymerization initiator (B), and a polysiloxane (C) represented by Formula (c). The curable composition contains the polysiloxane (C) in an amount of 0.01% to 5% by weight based on the total amount of the curable composition. The curable composition according to the present invention for lens formation may further contain a siloxane compound (D) containing two or more epoxy groups per molecule. ##STR00001##

A method for packaging applies to packaging a plurality of wafer-level lenses. Each wafer-level lens includes (a) a substrate with opposite facing first and second surfaces and (b) a respective lens element on at least one of the first and second surfaces. Each lens element has a lens surface facing away from the substrate. The method includes partially encasing the plurality of wafer-level lenses with a housing material to produce a wafer of packaged wafer-level lenses. In the wafer of packaged wafer-level lenses, the housing material supports each of the plurality of wafer-level lenses by contacting the respective substrate, and the housing is shaped to form a plurality of housings for the plurality of wafer-level lenses, respectively.

The present invention relates to method of fabricating a wafer level optical lens assembly. The method includes providing a wafer substrate having a plurality of lens shapes arranged side by side, and providing a spacer substrate having a plurality of spacer posts. The method further includes applying a first polymer liquid on a specific location chosen from the group of: (1) positions located on the wafer substrate between the plurality of lens shapes; (2) positions located on the contact surface of the spacer posts; and (3) a combination thereof. The method further includes contacting the wafer substrate with the spacer substrate such that the spacer posts force the first polymer liquid to flow towards the lens shapes, followed by curing the first polymer liquid, and applying a second polymer liquid onto the lens shapes.

Manufacturing optoelectronic modules includes supporting a printed circuit board substrate (27) on a first vacuum injection tool (24). The printed circuit board substrate (27) has at least one optoelectronic component mounted thereon and has a solder mask (40) on a surface (46) facing away from the first vacuum injection tool (24). The method includes causing the first vacuum injection tool (24) and a second vacuum injection tool (22) to be brought closer to one another such that a surface (46) of the second vacuum injection tool (22) is in contact with the solder mask (40). Subsequently, a first epoxy (100, 20) is provided, using a vacuum injection technique, in spaces (104) between the upper tool (22) and the solder mask (40).

The present technology relates to, for example, a lens attached substrate including a substrate which has a through-hole formed therein and a light shielding film formed on a side wall of the through-hole and a lens resin portion which is formed inside the through-hole of the substrate. The present technology can be applied to, for example, a lens attached substrate, a layered lens structure, a camera module, a manufacturing apparatus, a manufacturing method, an electronic device, a computer, a program, a storage medium, a system, and the like.

The invention relates to wafer-level manufacturing of optical devices such as modules comprising micro-lenses. In one aspect, passive optical components such as truncated lenses are manufactured by providing a substrate on which a multitude of precursor optical structures is present; and removing material from each of said multitude of precursor optical structures. Another aspect comprises a method for manufacturing a device comprising a set of at least two passive optical components, said method comprising the steps of using a tool obtained by carrying out the steps of manufacturing a precursor tool having a replication surface; and modifying said replication surface by removing material from said precursor tool. An yet another aspect comprises a method for manufacturing a device comprising a set of at least two passive optical components, wherein the method comprises the step of using a master comprising a replication surface comprising, for each of said passive optical components, a first portion describing a shape corresponding to the shape of at least a portion of the respective passive optical component, wherein the master comprises, in addition, at least one protruding portion protruding from at least one of said first portions of said replication surfaces.

A replication tool for producing an optical structure comprising an optical element includes a central section having the shape defining a negative of a portion of the optical structure and a vertically aligned central axis; a surrounding section laterally surrounding the central section; and one or more contact standoffs defining a plane referred to as contact plane. In a first azimuthal range, the surrounding portion provides a first compensation surface facing away from the central axis, and in a second azimuthal range, the surrounding portion provides a second compensation surface facing away from the central axis. In any cross-section containing the central axis in the second azimuthal range, a steepness of the second compensation surface is higher than a steepness of the first compensation surface in any cross-section containing the central axis in the first azimuthal range.

Fabricating optical devices can include mounting a plurality of singulated lens systems over a substrate, adjusting a thickness of the substrate below at least some of the lens systems to provide respective focal length corrections for the lens systems, and subsequently separating the substrate into a plurality of optical modules, each of which includes one of the lens systems mounted over a portion of the substrate. Adjusting a thickness of the substrate can include, for example, micro-machining the substrate to form respective holes below at least some of the lens systems or adding one or more layers below at least some of the lens systems so as to correct for variations in the focal lengths of the lens systems.

The method for manufacturing an object comprises the steps of (a) providing a wafer comprising a multitude of semi-finished objects; (b) separating said wafer into parts referred to as sub-wafers, at least one of said sub-wafers comprising a plurality of said semi-finished objects; (c) processing at least a portion of said plurality of semi-finished objects by subjecting said at least one sub-wafer to at least one processing step; and preferably also the step of (d) separating said at least one sub-wafer into a plurality of parts.

To prevent the resin from oozing out during the lens molding due to the capillary action. A laminated lens structure according to the present disclosure includes: a plurality of lens structures including a substrate provided with an opening part, a lens inserted into the opening part to be fixed to the substrate, and a recessed part provided at an area in which a lateral face of the opening part and a surface of the substrate are intersected, and recessed more than the surface of the substrate. The lenses are arrayed in an optical axis direction by the substrates being joined. This configuration makes it possible to prevent the resin from oozing out during the lens molding due to the capillary action.