The present invention provides a receptacle structure for an optical connector comprising a receptacle body, and a first housing. The receptacle body has a first end and a second end for providing optical connector inserted thereto, respectively. Two sides of the first end respectively have first flexible plate having first attaching structure. The first housing, folded by a single piece material, is a closed structure having a first through hole wherein two walls of the first housing have first coupling structure for coupling to the attaching structure when the first end of the receptacle body is inserted into the first through hole whereby the first housing is completely assembled with the receptacle body. In addition, an optical communication device having the receptacle structure is also provided in which the optical connector can be inserted into the receptacle structure for optical communication.

An optical module includes an interface electrically connected to an external device to receive a data signal to be transmitted, a signal processor configured to perform serialization and signal modulation on the received data signal, an optical transceiver configured to generate an optical transmission signal by receiving a direct current (DC) light source, in which a plurality of light sources having different wavelengths are multiplexed, from an optical power supply and performing optical modulation thereon through the serialized and modulated data signal, and an optical fiber connector configured to output the generated optical transmission signal to the external device and receive an optical reception signal from the external device.

There is provided an optical connector-incorporating plug properly assembled such that an optical fiber taken out from an end portion of an optical cable can have a fixed length. The optical connector-incorporating plug of the invention includes: a cable insertion component having an insertion hole in which an optical cable is inserted with an optical fiber being taken out from a cable end portion of the optical cable; a tubular member in which the cable end portion and the optical fiber are placed and in which the cable insertion component is fitted; a hole formed at a peripheral wall of the tubular member to check at least one of the cable end portion and the optical fiber in the tubular member; and a surrounding member mounted to the tubular member to surround the portion of the tubular member where the cable insertion component is fitted, thereby covering the hole.

Technologies for switching network traffic include a network switch. The network switch includes one or more processors and communication circuitry coupled to the one or more processors. The communication circuity is capable of switching network traffic of multiple link layer protocols. Additionally, the network switch includes one or more memory devices storing instructions that, when executed, cause the network switch to receive, with the communication circuitry through an optical connection, network traffic to be forwarded, and determine a link layer protocol of the received network traffic. The instructions additionally cause the network switch to forward the network traffic as a function of the determined link layer protocol. Other embodiments are also described and claimed.

An optical connector for a photonic circuit. The optical connector includes a first part, fixable to a photonic circuit, having at least one slab of optically transparent material, the at least one slab including a first lens. The optical connector includes a second part, movable between a connected position adjacent the first part and a disconnected position removed from the first part. The second part includes at least one slab of optically transparent material, the at least one slab including a second lens located to be in alignment with the first lens in the connected position. One or more guiding elements are arranged to direct light to the second lens. The second part is configured to connect the one or more guiding elements to an optical fiber.

In one embodiment, a module for plugging into a QSFP-DD (Quad Small Form Factor Pluggable Double Density) cage is provided that has one or more projections for contacting a QSFP-DD optical module in an adjacent QSFP-DD recess of the QSFP-DD cage so as to evacuate heat from, and or provide power to, the QSFP-DD optical module.

Provided is a photoelectric conversion module plug that includes a photoelectric hybrid board, a circuit board, an optical connector, and a plug case that houses them. At least a part of the photoelectric hybrid board faces the circuit board. The plug case has a thickness T2 in a facing direction between the photoelectric hybrid board and the circuit board. The ratio of the thickness T1 of the optical connector with respect to the thickness T2 of the plug case is 30% or more. The plug case has side walls having uneven region portions respectively and at least a part of the optical connector is located between the uneven region portions. An optical cable according to the present invention includes the module plugs and an optical cable that optically connects between these module plugs.

Fiber optic network systems are implemented, at least in part, using very small form factor (VSFF) interconnect components such as VSFF duplex connector; VSFF mechanical transfer ferrule (MT) connector; VSFF duplex uniboot connector; VSFF MT uniboot connector; VSFF duplex adapter; VSFF MT adapter; VSFF duplex pluggable transceiver; VSFF MT pluggable transceiver; VSFF patch cable assembly; VSFF trunk cable; and/or VSFF breakout cable. The VSFF fiber optic network systems can define fiber breakout cabling that connects large trunk cables to many peripheral network locations. The network systems can define branches and sub-branches from a trunk cable. The network systems can define cross-connect sub-networks between sets of transceivers or adapters. The network systems can define a trunk-to-transceiver cabling assembly for connecting a trunk cable to at least 32 transceiver ports.

A pluggable optical module includes: a casing with an internal space; a latching pocket disposed on a side wall of the casing; and a latch plane on a surface of the latching pocket. The surface is a beveled surface, and the beveled surface delimiting the latch plane has an angle of between 3 to 15 degrees.

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.