Abstract: The present disclosure relates to a fiber optic network including a plurality of fiber distribution components daisy chained together to form a chain of fiber distribution components, the chain of fiber distribution components having a first set of optical fiber paths that are indexed along a length of the chain and a second set of optical fiber paths that are not indexed along a length of the chain.

Abstract: An optical assembly includes a carrier plate, a light emitting element and a lens component disposed on the carrier plate, and a securing block. The securing block has a first surface and a light-passing portion that are located on an optical path of an output light from the light emitting element. The lens component includes a lens portion and a connecting portion. The lens portion is located on the optical path. The connecting portion has a second surface facing the first surface of the securing block. A bottom surface of the securing block is bonded to the carrier plate. The lens component is secured onto the carrier plate by means of bonding between the second surface and the first surface of the securing block. A clearance space is present between the lens portion and the light-passing portion so that the lens portion does not contact the securing block.

Abstract: Embodiments of a pre-mold assembly for a distribution cable having one or more tether cables are provided. The assembly includes a first shell having a first inner surface and a first outer surface, a second shell having a second inner surface and a second outer surface, and a clip that couples the first shell to the second shell. The clip has a first leg configured to engage the first outer surface of the first shell and a second leg configured to engage the second outer surface of the second shell. In an assembled state, the inner surfaces of the shells define a first channel configured to hold the distribution cable. Further, the inner surfaces of the shells define a second channel that originates within the shells. The second channel is angled relative to the first channel and is configured to hold the one or more tether cables.

Abstract: A fiber optic cable splice assembly includes: a first fiber optic cable having a first optical fiber with an exposed first exposed splice region, a first ribbon portion adjacent the first optical fiber and a first jacket; a second fiber optic cable having a second optical fiber with an exposed second splice region, a second ribbon portion adjacent the second optical fiber and a second jacket, the second optical fiber fusion-spliced to the first optical fiber; a splice protector that overlies the first and second exposed splice regions; and a first fiber boot attached to the splice protector that overlies the first ribbon portion.

Abstract: A method of protecting a fusion splice of first and second fiber optic cables includes: (a) providing a first member; (b) providing a second member formed of an activatable material; (c) positioning the fusion splice adjacent the first member and the second member; and (d) activating the second member to cause the second member to flow over the fusion splice and to engage the first member such that the activatable material at least partially surrounds the fusion splice.

Abstract: The present disclosure discloses a modular hardened optical fiber connector and an assembly method thereof. The modular hardened optical fiber connector comprises: a ferrule stub module which comprises a pre-installed optical fiber; an optical cable holding module which comprises an optical drop fiber of an optical drop cable; an optical fiber protection module which is arranged around a connection portion between the pre-installed optical fiber and the optical drop fiber; an inner housing module which accommodates the ferrule stub module, the optical cable holding module and the optical fiber protection module therein; and an outer housing module which accommodates the inner housing module therein.

Abstract: A fiber optic cable assembly includes a fiber optic cable and a fiber optic connector. The cable includes a jacket having an elongated transverse cross-sectional profile that defines a major axis and a minor axis. Strength components of the cable are anchored to the connector. The fiber optic connector includes a multi-fiber ferrule defining a major axis that is generally perpendicular to the major axis of the jacket and a minor axis that is generally perpendicular to the minor axis of the jacket. Certain types of connectors include a connector body defining a side opening that extends along a length of the connector body; a multi-fiber ferrule configured for lateral insertion into the connector body through the side opening; and a cover that mounts over the side opening after the multi-fiber ferrule has been inserted into the connector body through the side opening.

Abstract: An elastic member according to an embodiment is an elastic member that biases a ferrule retaining a plurality of optical fibers in a connecting direction. The elastic member is stored in an inner housing that accommodates the ferrule, the elastic member has a space in its inside into which a 16-fiber tape fiber is inserted, and the elastic member is in a noncircular shape in a cross section intersecting with the connecting direction. The elastic member includes a pair of first portions having an outer surface opposite to a pair of inner surfaces in an arc shape of the housing, the inner surfaces being opposite to each other along a first direction intersecting with the connecting direction and a pair of second portions opposite to the tape fiber along a second direction intersecting with both of the connecting direction and the first direction.

Abstract: An electronic device may have a housing with a display. A protective display cover layer for the display may have an image transport layer such as an image transport layer formed from optical fibers. Extruded filaments of binder material may be fused together to form a layer of binder for the image transport layer. Each filament may contain multiple embedded optical fibers. As a result of the extrusion process, the optical fibers may be characterized by increasing lateral deformation at increasing distances from the center of the filament in which the optical fibers are embedded. Tension variations and variations in the orientation angle of the fibers in the image transport layer can be maintained below desired limits to ensure satisfactory optical performance for the image transport layer. The optical fibers and binder may be formed from polymers or other clear materials.

Abstract: A photonic die includes an optical component that can emit output light. The optical component includes a substrate having a length and width that are substantially greater than a thickness thereof, the thickness defining a vertical direction. The optical component includes a vertical edge, and a reflective or antireflective coating on the vertical edge, wherein the reflective or antireflective coating includes a silicon-based material.

Abstract: A structure includes an optical interposer attached to a package substrate, wherein the optical interposer includes a silicon waveguide, a first photonic component optically coupled to the silicon waveguide, a second photonic component optically coupled to the silicon waveguide, and an interconnect structure extending over the silicon waveguide, over the first photonic component, and over the second photonic component, wherein the interconnect structure is electrically connected to the first photonic component and to the second photonic component, a first semiconductor device attached to the interconnect structure, wherein the first semiconductor device is electrically connected to the first photonic component through the interconnect structure, and a second semiconductor device attached to the interconnect structure, wherein the second semiconductor device is electrically connected to the second photonic component through the interconnect structure.

Abstract: Disclosed is a connecting harness that connects M first devices (where M is an integer equal to or greater than 1) and N second devices (where N is an integer equal to or greater than 2) using connecting cords each including at least one of an optical fiber cord and a metal cord. The connecting harness includes a connecting cord group including the M×N connecting cords, in which first connectors capable of being connected to the first devices are provided at one end of each of the connecting cords and second connectors capable of being connected to the second devices are provided at the other end of each of the connecting cords; a first bundling member bundling the connecting cords of the connecting cord group beside the first device in a predetermined number; and a second bundling member bundling the connecting cords of the connecting cord group beside the second device in a predetermined number.

Abstract: Embodiments of the disclosure relate to a method of preparing a bundled cable. In the method, a plurality of subunits is wound around a central member in one or more layers of subunits to form the bundled cable. For a section of the central member, each layer of subunits has a pitch over which a subunit of the layer of subunits makes one revolution around the section of the central member and a length of the subunit required to make the one revolution. The subunits are configured to have a nominal helical length equal to the ratio of a nominal length to a nominal pitch. Further, in the method, a measurement of the bundled cable is monitored, and a winding rate of the plurality of subunits is adjusted based on the measurement in order to account for deviations from the nominal helical length.

Abstract: A device comprises first, second and third elements fabricated on a common substrate. The first element comprises an active waveguide structure comprising: one portion, of effective cross-sectional area A1, supporting a first optical mode; and a second portion, butt-coupled to the first portion, of effective cross-sectional area A2>A1. The second element comprises a passive waveguide structure supporting a second optical mode. The third element, at least partly butt-coupled to the second portion, comprises an intermediate waveguide structure supporting intermediate optical modes. If the first optical mode differs from the second optical mode by more than a predetermined amount, a tapered waveguide structure in at least one of the second and third elements facilitates efficient adiabatic transformation between the first optical mode and one intermediate optical mode. No adiabatic transformation occurs between any intermediate optical mode and the first optical mode.

Abstract: An optical fiber holder for holding an optical fiber includes a holder body part on which a first optical fiber and a second optical fiber having a different outer diameter are mountable, a lid body which is disposed to the holder body part, and a fiber posture correction block which is provided on the lid body on a side close to a terminal processing part of the first optical fiber and the second optical fiber. The holder body part includes a first regulating part at an end part thereof on a terminal processing part side, and the first regulating part regulates movement of a first glass fiber of the first optical fiber and a second glass fiber of the second optical fiber. The fiber posture correction block includes a contact part to contact the second optical fiber at an end part thereof on the terminal processing part side.

Abstract: An optical fiber drop cable. The optical fiber drop cable includes at least one optical fiber and at least one inner tensile element wound around the at least one optical fiber having a laylength of at least 200 mm. The optical fiber drop cable also includes an interior jacket disposed around the at least one inner tensile element and an exterior jacket having an inner surface and an outer surface. The optical fiber drop cable further includes at least one outer tensile element disposed between the interior jacket and the outer surface of the exterior jacket. Each of the at least one outer tensile element has a laylength of at least 1 m. The exterior jacket includes at least one polyolefin, at least one thermoplastic elastomer, and at least one high aspect ratio inorganic filler. The exterior jacket has an averaged coefficient of thermal expansion of no more than 120(10?6) m/mK.

Abstract: A plurality of bandpass filters (2) are arranged side by side in a row on a fixed surface (1a) of a glass block (1) and fixed using an adhesive (3). Each bandpass filter (2) includes a coating film (6) for transmitting or reflecting light depending on a wavelength. Each bandpass filter (2) includes a first surface (2a) fixed to the fixed surface (1a), and a second surface (2b) opposite to the first surface (2a) and having a width larger than that of the first surface (2a). Opposing side surfaces of the adjacent bandpass filters (2) include a first portion (2c) on the first surface (2a) side and a second portion (2d) on the second surface (2b) side. A spacing between the first portions (2c) of the adjacent bandpass filters (2) is wider than a spacing between the second portions (2d) of the adjacent bandpass filters (2).

Abstract: An example apparatus includes an optical fiber, an actuator, and a joint mechanically coupling the actuator to the optical fiber. The joint includes a neck extending along an axis. The optical fiber is threaded through an aperture extending along the axis through the neck. The optical fiber is attached to the joint at a surface of the neck facing the axis. The joint also includes a collar extending along the axis. The actuator is mechanically attached to the joint at an inner surface of the collar facing the axis. The joint also includes a flexural element extending radially from the neck to the collar. During operation, the joint couples a force from the actuator to the optical fiber to vary an orientation of a portion of the optical fiber extending from the neck with respect to the axis.

Abstract: A photoelectric conversion element includes a substrate including a lens-shaped convex portion and an annular concave portion surrounding the lens-shaped convex portion on a first main surface; a photoelectric conversion layer, positioned on an optical path of light passing through the lens-shaped convex portion, on a second main surface side of the substrate; and a pattern disposed on an outer peripheral side of the annular concave portion on the first main surface and disposed to interpose the lens-shaped convex portion from a first direction and a second direction intersecting the first direction.

Abstract: Structures that include a Bragg grating and methods of fabricating a structure that includes a Bragg grating. The structure includes a waveguide core and a Bragg grating having a plurality of segments positioned with a spaced arrangement adjacent to the waveguide core. Each segment includes one or more exterior surfaces. The structure further includes a silicide layer located on the one or more exterior surfaces of each segment.