An imaging lens assembly includes a dual molded optical element, a plurality of imaging lens elements and a light blocking element. The dual molded optical element has an object-side surface and an image-side surface and includes a light transmitting portion and a light absorbing portion. The light transmitting portion includes an optical effective section. The light absorbing portion is located on at least one of the object-side surface and the image-side surface of the dual molded optical element, and a plastic material of the light absorbing portion and a plastic material of the light transmitting portion are different colors. The imaging lens elements are disposed in the inner space of the imaging lens assembly. The light blocking element is disposed adjacent to the light transmitting portion of the dual molded optical element.

A lens unit may include a plurality of lenses; and a cylindrical holder. The plurality of lenses may include a cemented lens having a second lens element bonded to a first lens element with an adhesive layer interposed therebetween. The first lens element may be a plastic lens having a convex lens surface and a first flange unit at an outer peripheral side. The second lens element may be a plastic lens having a concave lens surface bonded by the adhesive layer onto the convex lens surface of the first lens element and a second flange unit at an outer peripheral side. One of the first and second lens elements may be in contact with the holder, and the may not be in contact with the holder. The first and second cemented lens elements may include an optical axial direction abutment surface and a radial direction abutment surface.

A lens unit includes a plurality of lenses, and a holder in a tube shape which holds the plurality of the lenses. An inner peripheral face of the holder is formed with a plurality of alignment protruded parts protruded from the inner peripheral face to an inner side in a circumferential direction, each of the alignment protruded parts is provided with a first alignment protruded part whose protruding dimension is different and a second alignment protruded part, and the second alignment protruded part is protruded from the first alignment protruded part to the inner side of the inner peripheral face to be abutted with an outer peripheral face of one of the lenses.

A compound lens and a related method of manufacture are provided. The compound lens includes a first lens element and a second lens element such that a light emitting surface of the first lens element is integrally joined to a light receiving surface of the second lens element, the first and second lens element being in optical alignment with each other. The first and second lens element are molded from optical grade silicone and can achieve complex illumination objectives not possible with single lens constructions. The method of manufacture includes injecting a silicone resin molding compound into a mold cavity having the desired shape of the compound lens. The method of manufacture can include over-molding a lens holding member onto the compound lens and adding electro-optically active particles to a surface of the compound lens or to the silicone resin forming the compound lens.

The invention relates to an ophthalmic lens (1), in particular for sunglasses, comprising: a first outer layer (9) of transparent substrate, comprising a rear face (9.sub.AR), intended to be orientated towards the eye of a user of said ophthalmic lens (1), and a front face (9.sub.AV) intended to be orientated towards the field of vision (13) of the user, intended to form the convex, front outer surface of the ophthalmic lens (1), a second outer layer (10) of transparent substrate, comprising a rear face (10.sub.AR) orientated towards the eye of the user, intended to form the concave, rear outer face of the ophthalmic lens (1) orientated towards the eye of the user, and a front face (10.sub.AR) orientated towards the field of vision of the user, characterized in that the lens further comprises an interferometric mirror (21) disposed between the first outer layer (9) and the second outer layer (10).

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.

An optically active material set can include a particulate build material including polymer particles having an average particle size from 10 m to 100 m, wherein the particulate build material as a whole has a transparency from 85% to 100%. The material set can further include an inkjettable fluid for application to the build material for 3D printing, wherein the inkjettable fluid may include dielectric nanoparticles having an average particle size from 1 nm to 100 nm.

A manufacturing method of an optical unit for endoscope includes: a process of crimping a bonding sheet including a curable resin film to a release substrate having a release surface which is an optical flat surface; a mirror-finishing process of performing a partial curing treatment on a predetermined region of the bonding sheet to process the predetermined region into an optical flat surface; a process of fabricating a laminated wafer by laminating a first element wafer including a first optical element and a second element wafer including a second optical element, with the bonding sheet being arranged between the first element wafer and the second element wafer; a curing process of performing a curing treatment on an uncured region of the bonding sheet; and a process of cutting the laminated wafer and segmenting the laminated wafer into optical units.

A lens unit is provided that includes: a first lens that is housed inside a lens-barrel, the first lens including a first lens section and a first flange section that juts out from the first lens section in a direction orthogonal to an optical axis direction; a second lens that is housed inside the lens-barrel further toward an imaging plane side than the first lens, the second lens including a second lens section and a second flange section that juts out from the second lens section in a direction orthogonal to the optical axis direction; and a spacing ring that is sandwiched between the first lens and the second lens and that defines a spacing between the first lens and the second lens, the spacing ring includes a main body disposed between the first flange section and the second flange section in the optical axis direction, first protrusion portions that protrude in the optical axis direction from an object side of the main body, and second protrusion portions that protrude in the optical axis direction from the imaging plane side of the main body and are disposed offset with respect to the first protrusion portions when projected along the optical axis direction.

A method of producing a lens unit includes forming a layer by switching between a transmissive material that allows transmission of light and a light-shielding material that shields light, and stacking formed layers to form a lens from the transmissive material and forma barrel that holds the lens from the light-shielding material.