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.

To provide an optical connector and an optical transmission module that are suitable for a plurality of optical transmission paths two-dimensionally arranged. An optical connector according to the present technology is an optical connector for a plurality of optical transmission paths arranged in a two-dimensional array and includes a first lens, a second lens, a third lens, and a fourth lens. The first lens reflects emitted light from a first optical transmission path of the plurality of optical transmission paths. The second lens reflects emitted light from a second optical transmission path of the plurality of optical transmission paths. The third lens collimates light reflected by the first lens. The fourth lens collimates light reflected by the second lens.

Assemblies, optical connectors, and methods for bonding optical elements to a substrate using a laser beam are disclosed. In one embodiment, a method of bonding an optical element to a substrate includes disposing a film layer on a surface of the substrate, disposing the optical element on a surface of the film layer, and directing a laser beam into the optical element. The method further includes melting, using the diameter laser beam, a material of the substrate to create a bond area between the optical element and the surface of the substrate. The film layer is capable of absorbing a wavelength of the laser beam to melt the material of the substrate at the bond area. The bond area includes laser-melted material of the substrate that bonds the optical element to the substrate.

A retention assembly for coupling a cable including a plurality of optical fibers to a support may include a retention anchor configured to be coupled to a support and a retention coupler configured to be coupled to a cable. The retention anchor may include a mounting plate configured to be coupled to a support and defining an entry hole extending through the mounting plate and an engagement slot extending from a periphery of the entry hole. The retention coupler may include a retention support and a retainer blade coupled to a first coupler face of the retention support via an extension. The retainer blade may be configured to be passed through the entry hole, such that the extension extends through the entry hole of the mounting plate, and the extension slides within the engagement slot of the mounting plate.

A splice enclosure for providing a space for receipt of a plurality of spliced optical fibers of a plurality of cables may include a cabinet including a rear wall, a first side wall coupled to the rear wall, and a second side wall coupled to the rear wall. The cabinet may also include a lower wall coupled to the first side wall, the second side wall, and/or the rear wall. The splice enclosure may further include a splice tray assembly, which may include a splice tray housing pivotally coupled to the cabinet, and a plurality of splice trays pivotally coupled to the splice tray housing and configured to provide a space for receipt of a plurality of spliced optical fibers of a plurality of cables. The splice tray housing may be pivotally coupled to the cabinet, such that the splice tray housing pivots.

A splice tray may include a tray base including a base panel and flange associated with a perimeter of the base panel and extending outward from the base panel. The splice tray may also include a flexible latch extending from an outer surface of the flange of the tray base. The latch may selectively prevent and allow the splice tray to pivot with respect to a splice tray assembly in which the splice tray is received. The splice tray may also include a splice holder configured to hold a plurality of spliced optical fibers. The splice holder may include a holder base coupled to the tray base, and a plurality of ribs associated with the holder base and defining a plurality of recesses configured to receive at least one spliced optical fiber. The splice tray may also include a cover removably coupled to the tray base and/or splice holder.

Methods, systems, and computer readable media can be operable to facilitate an improved positioning of one of more LEDs on a device. A CPE (customer premise equipment) device may include a three-component subassembly composed of an LED module, light tube, and lightguide to allow for uniform lighting with design flexibility. The modularity of the design allows for decoupling from the PCB and reduces the design constraints.

A probe device is configured to insert optical fiber probes directly into a v-groove coupler on an optical integrated circuit (IC) device. The probe device may include a probe holder comprising with a slot. A fiber holder may insert into the slot. The fiber holder may comprise a body with a first portion and second portion disposed at an angle relative to one another so that the first portion is shorter than the second portion. The body may have a bottom with grooves disposed therein, the grooves having dimensions to receive part of an optical fiber probes therein. In use, the fiber holder can arrange the optical fiber probes to extend into the v-grooves of the v-groove coupler of an optical IC on a wafer. The device may incorporate an alignment mechanism that permits the fiber holder to move or self-align in response to contact between the optical fiber probes and structure of the v-groove coupler of an optical IC on a wafer.

Disclosed is an optical interconnection device that includes an alignment ferrule assembly formed from an alignment substrate and optical fibers. The optical interconnection device also has an alignment assembly formed by a planar support member with guide features. A receiving region resides between the guide features in which the alignment substrate is secured. An evanescent optical coupler can be formed using the optical interconnection device as a first device and another optical interconnection device as a second device. The second device is constituted by a planar lightwave circuit that operably supports waveguides and an adapter. The adapter of the second device is configured to engage the alignment assembly of the first device to place the optical fibers and the optical waveguides of the respective devices in evanescent optical communication.

An optical rotary joint for optical signal transmission is described, said optical rotary joint having at least two units that are respectively rotatably mounted about an axis of rotation, the axes of rotation of which, at least in sections, have a lateral distance from one another. The invention is distinguished by a rotary transformer that is embodied in the form of an endless loop respectively resting in a circumferential manner on both units along a contact region and positively coupling the at least two units with one another in a rotationally movable manner. Attached to both units is respectively one optical unit for conjoint rotation, said optical unit comprising at least one optical signal line, a beam splitter and/or beam coupler, which is optically coupled to the at least one optical signal line, and at least two optical partial signal lines, said optical unit being optically coupled to the at least one optical signal line via the beam splitter and/or beam coupler. Moreover, at least two optical transmission lines are attached to the rotary transformer. Finally, optical coupling means are attached to the rotary transformer and optical coupling means are attached to the units, which respectively serve for detachable optical signal coupling between one of the partial signal lines and one of the optical transmission lines.