The present disclosure describes sealing boots for protecting an optical interconnection. A sealing boot may include a main body having an interior cavity, the interior cavity having an annular recess adjacent to one end of the main body, the annular recess configured to receive a feature of a remote radio unit, and a neck merging with the opposing end of the main body and having a cylindrical inner surface that defines a bore that is continuous with the cavity of the main body, the inner surface having an inner diameter that is less than an inner diameter of the interior cavity of the main body. The sealing boot is configured to surround at least a portion of a fixed active optical connector when the fixed active optical connector is plugged into the remote radio unit.

Provided is an opto-electric transmission composite module and an opto-electric hybrid board, both of which can suppress the reduction in the function of an optical element when a driver element generates heat. The opto-electric transmission composite module includes: an opto-electric hybrid board including an optical waveguide, and an electric circuit board including a first terminal for mounting an optical element; and a printed wiring board including a fourth terminal for mounting a driver element. The printed wiring board is electrically connected with the electric circuit board.

An optical transceiver for connection between an optical socket and an electrical socket is disclosed. The optical transceiver includes an electrical connector and an optical connector. The optical transceiver has an electronics housing holding the electrical and optical connectors in relative position to each other allowing the simultaneous connection to an electrical socket and an optical socket. The electrical and optical connectors may be moved between an extended position and a retracted position relative to the electronics housing when being engaged or disengaged with respective electrical and optical sockets.

An optical transceiving device includes a housing including opposite lateral surfaces, a fastening component movably disposed on the housing, and a bail assembly including a carrier, a handle and a securing structure. The fastening component includes a linkage arm and two extending arms connected with the linkage arm. The two extending arms configured to be detachably fastened with a cage. The carrier is fixed to the fastening component. The carrier and the linkage arm jointly define an accommodation space having an opening. The handle is disposed on the carrier and movable along a release direction to be at either a close position or an open position. The handle is held in the accommodation space by the securing structure when at the close position. The handle protrudes from the opening when at the open position, and brings the fastening component to move together.

A cable assembly may include a first end and a second end. The first end may include a first breakout including a plurality of transmissive conduits implementing a plurality of communications channels and a second breakout including a plurality of conduits implementing a plurality of communications channels. The second end may include a third breakout including a plurality of conduits implementing a plurality of communications channels and a fourth breakout including a plurality of conduits implementing a plurality of communications channels. Communication channels of the first breakout, second breakout, third breakout, and fourth breakout may be arranged such that the first breakout shares a first communications channel with the third breakout, the first breakout shares a second communications channel with the fourth breakout, the second breakout shares a third communications channel with the third breakout, and the second breakout shares a fourth communications channel with the fourth breakout.

A waveguide substrate configured includes a first surface, a second surface opposite the first surface, and a communication side having at least one projecting boss that at least partially defines a bore for receiving a ferrule of an optical connector. Each projecting boss includes an outboard end from which the bore extends into the waveguide substrate, and an end of the bore within the waveguide substrate defines an optical interface surface. At least one waveguide within the waveguide substrate extends from the optical interface surface. A first slot is formed in each projecting boss between the associated bore and the first surface, with the first slot extending from the outboard end of the projecting boss and along a majority of the bore.

A photonic coupler includes an input coupling section, an output coupling section, and a multimode interference (MMI) waveguide section. The input coupling section is adapted to receive an input optical signal along an input waveguide channel. The output coupling section is adapted to output a pair of output optical signals along output waveguide channels. The output optical signals having output optical powers split from the input optical signal. The MMI waveguide section is optically coupled between the input and output coupling sections. Notched waveguide sections may each be disposed between the MMI waveguide section and a corresponding one of the input or output coupling sections and/or the MMI waveguide section may include curvilinear sidewalls.

A computing device, comprising: a chassis; an optical base layer, including optical connectors; a power base layer, including power connectors; a thermal base layer, including a cold supply line with liquid disconnects, hot return lines with liquid disconnects, and thermal infrastructure interfaces; a radio frequency base layer, including radio frequency connectors; a power interface, wherein the power interface connects to the power base layer; a power supply to connect to the power interface and provide power to the power base layer through the power interface; and bays defined by bay divider walls, wherein each bay divider wall is removable and each bay comprises one of the optical connectors, one of the power connectors, one liquid disconnect for the supply line, one of the liquid disconnects for a hot return line, and one of the radio frequency connectors.

An octal small form factor pluggable (OSFP) and an assembly method thereof are provided. The OSFP includes a base, spacer and lid. The base includes four optical fiber ports located at four corners of an imaginary rectangle, respectively, a receiving portion and a holder. The optical fiber ports are disposed at a front end of the base. The receiving portion is near the optical fiber ports and has a receiving space. The holder is in the receiving space and near two lower ones of the optical fiber ports. Two terminal-shaped dent portions are disposed on the holder and near the two lower optical fiber ports. The spacer is disposed above the holder. Terminal-shaped recess portions are disposed on the spacer, with lower ones clamping terminals together with the dent portions, and upper ones lying near the two upper optical fiber ports. The lid covers the receiving portion.

An optical transmission device is provided. A substrate includes an optical transmission channel exposed on its end surface, and a first positioning portion. A jumper includes a mounting portion abutting the end surface and a second positioning portion engaged to the first positioning portion. An optical fiber is mounted to the mounting portion, and the end surface of the optical fiber aligns with the optical transmission channel. The coupling method of the optical transmission device includes steps: forming at least one first hole on the substrate, forming an optical transmission layer with at least one optical transmission channel on the substrate, forming an alignment mark on the optical transmission layer within the first hole, forming at least one second hole on the substrate based on the alignment mark, and connecting the jumper to the second hole and make the jumper abutting against the substrate.