Provided is a curable composition which has chargeability into silicone molds and curability at excellent levels, less causes the silicone molds to swell, and allows the silicone molds to have better durability and a longer service life in repeated use. The curable composition according to the present invention contains curable compounds and a cationic initiator and is used for production of an optical component by molding using silicone molds. The curable compounds include (A) a cycloaliphatic epoxy compound in a content of 10 weight percent or more of the totality of all the curable compounds contained in the curable composition. Of the totality of all the curable compounds contained in the curable composition, 10 to 50 weight percent is a curable compound or compounds having a molecular weight of 400 or more.

An athermal lens system includes a converging lens element having a negative first thermo-optic coefficient, and a diverging lens element having a second thermo-optic coefficient more negative than the first thermo-optic coefficient, wherein the diverging lens element is coupled with the converging lens element to form a converging athermal doublet lens.

The present disclosure relates to a stacked lens structure and a method of manufacturing the same, and an electronic apparatus by which it is possible to realize miniaturization of a lens module. A stacked lens structure includes plural substrates with lens stacked on one another, the substrate with lens each having a lens disposed on inside of a through-hole formed in the substrate. In regard of side surfaces at side parts corresponding to sides of a rectangle surrounding the substrate with lens in plan view as viewed in an optical axis direction, a width and a shape are the same among all the substrates with lens, whereas in regard of side surfaces at opposite angle parts corresponding to opposite angles of the rectangle, the width or shape differs between at least two substrates with lens. The present technology is applicable, for example, to a lens module or the like.

Provided is a mold for molding a wafer lens, including an upper mold and a lower mold. The upper mold includes a first molding surface. The first molding surface includes first molding portions. The first molding portion includes a first recessed portion formed by recessing from the first molding surface. The lower mold matches the upper mold. The lower mold includes a second molding surface right facing the first molding surface. The second molding surface includes second molding portions. The second molding portion includes a first protrusion portion protruding from the second molding surface towards the first molding surface. The first molding portions and the second molding portions are disposed in one-to-one correspondence. The first molding portion further includes a second recessed portion formed by recessing from the first molding surface towards a direction facing away from the lower mold. The second recessed portion surrounds the first recessed portion.

Provided is a mold, including: a lower mold matching and molding a convex surface, and an upper mold corresponding to the lower mold. The lower mold includes a first lens molding surface right facing the upper mold. A molding cavity is formed between the first lens molding surface and the upper mold. The first lens molding surface recesses towards a direction facing away from the upper mold to form recessed portions and grooves surrounding the recessed portions. The groove is in communication with the recessed portion. Two adjacent grooves are in communication with each other. An exhaust passage is formed in the first lens molding surface. The exhaust passage communicates with the grooves and extends to an outer edge of the lower mold. In a process of molding the lens, air in the recessed portion is discharged to an outside of the mold through the groove and the exhaust passage.

Optical stack assemblies and fabrication techniques thereof. The optical stack assembly includes first and second sub-assemblies, each of which include a substrate and a sub-structure fixed to the respective substrate. Each sub-structures includes a respective first edge feature and a respective second edge feature that project away from the substrate of that sub-structure, each second edge feature being disposed laterally closer to an outer periphery of the respective sub-structure than the first edge feature of the same sub-structure. The first edge feature of the first sub-structure is in direct contact with the first edge feature of the second substructure, while the second edge feature of the first sub-structure and the second edge feature of the second sub-structure are attached to one another by adhesive. At least one of the first or second sub-structures includes an optical element on a same side of the sub-structure as the first and second edge features of that sub-structure. The optical element stack assembly further includes a spacer laterally surrounding, and moulded to, the first and second sub-assemblies.

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.

The method regards manufacturing devices by replication, wherein each of the devices comprises a device surface. The method comprises producing the devices from a replication material by replication using a replication tool (1), wherein the replication tool (1) comprises a tool material comprising replication sites (4) comprising a replication surface (5) each. Each of the replication surfaces (5) corresponds to a negative of the device surface of a respective one of the devices. The tool material comprises, in addition to the replication sites, one or more mitigating features (7) for reducing asymmetric form errors of the device surfaces. Replication tools (1) and methods for manufacturing these are also described.

A wafer-scale apparatus and method is described for the automation of forming, aligning and attaching two-dimensional arrays of microoptic elements on semiconductor and other image display devices, backplanes, optoelectronic boards, and integrated optical systems. In an ordered fabrication sequence, a mold plate comprised of optically designed cavities is formed by reactive ion etching or alternative processes, optionally coated with a release material layer and filled with optically specified materials by an automated fluid-injection and defect-inspection subsystem. Optical alignment fiducials guide the disclosed transfer and attachment processes to achieve specified tolerances between the microoptic elements and corresponding optoelectronic devices and circuits. The present invention applies to spectral filters, waveguides, fiber-optic mode-transformers, diffraction gratings, refractive lenses, diffractive lens/Fresnel zone plates, reflectors, and to combinations of elements and devices, including microelectromechanical systems and liquid crystal device matrices for adaptive, tunable elements. Preparation of interfacial layer properties and attachment process embodiments are taught.

The present disclosure relates to a camera package, a manufacturing method of a camera package, and an electronic device capable of reducing a manufacturing cost for forming a lens. The manufacturing method of the camera package according to the present disclosure includes forming a high-contact angle film around a lens forming region on an upper side of a transparent substrate that protects a solid-state imaging element, dropping a lens material in the lens forming region on the upper side of the transparent substrate, and molding the dropped lens material by a mold to form a lens. The present disclosure is applicable to, for example, a camera package and the like in which a lens is arranged above a solid-state imaging element.