A method of preparing an overmolded optical fiber assembly comprising: (a) placing at least one flexible optical circuit in a bottom mold, said bottom mold defining a bottom overmold cavity having a bottom surface, said at least one flexible optical circuit having a substrate and a plurality of fibers adhered to said substrate, said substrate being disposed within said bottom overmold cavity to define a first space between said substrate and said bottom surface; (b) flowing a polymer in at least said first space; (c) placing a top mold over said substrate, said top mold defining a top overmold cavity and a top surface and a port defined in said top surface to access said top overmold cavity, said substrate defining a second space between said top surface and said substrate; (d) flowing a polymer in at least a portion of said second space; and (e) removing said bottom and top molds to release said overmolded optical circuit.

A fixture is for forming a fiber optic array that defines a plurality of discrete fibers extending from a spaced-apart arrangement to a consolidated arrangement wherein the fibers are layered next to each other for a further ribbonizing process. The fixture includes a pair of contact blades that are configured to slide along a direction transverse to the longitudinal axes of the fibers for consolidating the fibers.

An optical connecting component configures to be mounted onto an optical component includes a plurality of optical fibers and terminal components disposed at the ends of the plurality of optical fibers. The optical fibers are arranged side by side and integrated together in a state in which the optical fibers can be separated from one another. A method of manufacturing an optical connecting component that includes a plurality of optical fibers and a terminal component disposed at ends of the plurality of optical fibers and that is mounted onto an optical component includes a step of arranging the plurality of optical fibers side by side and integrating the plurality of optical fibers together, a step of connecting end portions of the plurality of optical fibers to the terminal component, and a step of separating the plurality of optical fibers from one another.

A method and device for interconnecting optical components, such as optical fibers and optical circuits, in a flexible, repeatable, and cost-effective manner. Two or more optical components are interconnected by a flexible optical circuit substrate bearing one or more embedded optical fibers with a lens at each end of each fiber. The flexible optical circuit may be incorporated into a housing bearing apertures for receiving the optical connectors of the optical components that are to be interconnected with the device. The lensed ends of the fibers embedded in the flexible optical circuit are positioned adjacent to the apertures for optically connecting to the fibers within the connectors installed in the apertures without conventional mating connectors disposed inside the housing.

Flexible optical circuits and methods of providing the same in which routing of optical fibers on a flexible substrate is performed after optical fiber ends have been processed. In some embodiments, the methods include fiber splicing operations that can be performed on the pre-processed optical fibers before or after the fibers have been routed on the flexible substrate.

Provided is an optical module comprising a substrate, a holder, and a spacer. An optical waveguide is formed in/on the substrate and end parts thereof are protruding from one surface of the substrate. The holder holds an optical fiber and exposes one end part of the optical fiber in such a manner that the one end part of the optical fiber can be optically connected to the end parts of the optical waveguide at a side of one surface of the holder. The spacer is held the one surface of the substrate and the one surface of the holder.

Methods for laser welding one or more optical fibers to a substrate and assemblies are disclosed. In one embodiment, a method of bonding an optical fiber to a substrate having at least one film layer on a surface of the substrate includes directing a laser beam into the optical fiber disposed on the at least one film layer. The optical fiber has a curved surface that focuses the laser beam to a focused diameter. The method further includes melting, using the focused diameter laser beam, a material of the substrate to create a laser bond area between the optical fiber and the surface of the substrate. The laser bond area includes laser-melted material of the substrate that bonds the optical fiber to the substrate. The at least one film layer has an absorption of at least 15% at a wavelength of the focused diameter laser beam.

A method for forming an optical fiber array. A substrate having a first surface and an opposing second surface is provided. The substrate is provided with a plurality of apertures extending through the substrate from the first surface to the second surface. In addition, a plurality of fibers are provided. The fibers have fiber ends with a diameter smaller than the smallest diameter of the apertures. A first fiber is inserted in a first corresponding aperture, from the first surface side of the substrate, such that the fiber end is positioned in close proximity of the second surface. The inserted first fiber is bent in a predetermined direction such that the fiber abuts a side wall of the first aperture at a predetermined position. After the first fiber is bent, a second fiber is inserted in a second corresponding aperture, from the first surface side of the substrate, such that the fiber end is positioned in close proximity of the second surface. The inserted second fiber is bent in conformity with a shape of the first fiber, such that the fiber abuts a side wall of the second aperture at a predetermined position. The bent fibers are bonded together using an adhesive material.

A method of forming an optical fibre assembly, comprises providing a planar substrate made of a first material; positioning an optical fibre with an outer layer of a first glass material on a surface of the substrate to form a pre-assembly; depositing a further glass material such as silica soot onto the pre-assembly, over at least a part of the optical fibre and adjacent parts of the substrate surface; and heating the pre-assembly to consolidate the further glass material into an amorphous volume in contact with at least parts of the surface of the substrate and the outer layer of the optical fibre, thereby bonding the optical fibre to the substrate to create the optical fibre assembly.

A method and device for interconnecting optical components, such as optical fibers and optical circuits, in a flexible, repeatable, and cost-effective manner. Two or more optical components are interconnected by a flexible optical circuit substrate bearing one or more embedded optical fibers with a lens at each end of each fiber. The flexible optical circuit may be incorporated into a housing bearing apertures for receiving the optical connectors of the optical components that are to be interconnected with the device. The lensed ends of the fibers embedded in the flexible optical circuit are positioned adjacent to the apertures for optically connecting to the fibers within the connectors installed in the apertures without conventional mating connectors disposed inside the housing.