A transceiver assembly for mounting on a mother board, said transceiver assembly comprising: (a) a frame defining a first plane configured for mounting parallel to said motherboard, said frame defining a plurality of slots perpendicular to said first plane; and (b) one or more opto-electric cards, each of said one or more opto-electric cards disposed in one of said plurality of slots and comprising at least, (i) a substrate having a first edge parallel to said first plane when said opto-electric card is mounted in said slot, (ii) an electrical interface along said first edge, (iii) and an interposer electrically connected to said electrical interface and comprising at least one optical component operatively connected to said electrical interface, and (iv) at least one optical fiber extending freely from said interposer.

A plug mounted on an optical cable with one or more optical contacts each one having a tab which is deformable elastically or mounted so as to pivot relative to the rest of the contact, including: a body including a front part and a rear part; a bushing fitted around the front part with axial sliding forward, the bushing bearing a tab with an appendage extending inside the rear part, the tab of the bushing and the tab of each contact being disposed relative to each other so that when a traction force is applied to make the bushing slide around the front part, the appendage is able to bear against the tab of each contact so as to deform it elastically or make it pivot until the disconnection is produced between the contact and the converter.

The present invention concerns a plug intended to be mounted on at least one cable whose one end supports one or more contacts comprising: a body, comprising: a front portion extending along a longitudinal axis, the front portion being designed to be lodged in a socket, the front portion being adapted to lodge and hold the contact(s) or at least an optoelectronic converter connected to the contact(s); a rear portion forming a sheath, designed to lodge the end of the cable, itself supporting the contact(s); the rear portion being mounted floating about the front portion; a plurality of flexible tabs made of electrically conductive material, distributed on the outer periphery of the front portion, the flexible tabs being adapted to remain in mechanical contact with the interior of the socket when the front portion is lodged in the latter.

An optical receptacle connector includes a receptacle housing having housing walls defining a contact cavity and an optical cavity. The receptacle housing includes an upper wall and a lower wall at a front of the receptacle housing defining a card slot receiving a mating edge of an optical module circuit board of a pluggable optical generator module. The upper wall includes an upper wall opening above the card slot. A contact assembly having receptacle contacts is received in the contact cavity to supply power to the pluggable optical generator module to operate a light source of the pluggable optical generator module. A receive optical connector is coupled to the receptacle housing above the upper wall opening and mated with a supply optical connector of the pluggable optical generator module to receive optical signals from the supply optical connector.

A system includes a housing having a front panel, a substrate that is positioned at a distance from the front panel, and a data processor mounted on the substrate. The system includes a pluggable module having an optical module, at least one first optical connector, a first fiber optic cable optically coupled between the optical module and the first optical connector, and a fiber guide positioned between the optical module and the first optical connector and provides mechanical support for the optical module and the first optical connector. The optical module receives optical signals from the first optical connector and generates electrical signals based on the received optical signals, and the electrical signals are transmitted to the data processor. The pluggable module has a shape that enables the pluggable module to pass through an opening in the front panel to enable the optical module to be coupled to the substrate.

A photonic integrated circuit (PIC) device has photonic devices arranged in an array with respect to control and common conductors. Each of the photonic devices has a photonic component (e.g., photodiode, thermo-optic phase shifter, etc.) and a switching diode connected in series with one another between a control connection and a common connection. The photonic component has at least one optical port, which can be coupled to a waveguide in the PIC device. The switching diode is configured to switch between reverse and forward bias in response to the electrical signals. In this way, control circuitry for providing control and monitoring signals to the conductors can be greatly simplified, and the PIC device can be more compact.

An optical transceiver includes an outer part provided outside the apparatus upon an engagement of the optical transceiver with the apparatus. The outer part includes a first spindle, a rotational member, a sliding member. The rotational member is configured to rotate on the first spindle. The sliding member is configured to move along the first direction. The rotational member has a hole. The sliding member has a second spindle. The first spindle and the second spindle are fit with the hole. The optical transceiver includes an inner part provided inside the apparatus upon the engagement with the apparatus. The hole has a first circular area, a second circular area, and a straight area. The first spindle is fit with the first circular area. The second spindle is fit with the second circular area. The straight area is connected between the first circular area and the second circular area.

An optical cable laying construction set (X) that includes an optical cable (C1) and plugs (P1 and P2). The optical cable (C1) includes an optical fiber which is a refractive index distribution-type plastic optical fiber. The plug (P1) includes a connecting portion connectable to the optical fiber, and an electric connector connectable to an external device, and has a configuration for converting an electric signal into an optical signal. The plug (P2) includes a connecting portion connectable to the optical fiber, and an electric connector connectable to an external device, and has a configuration for converting an optical signal to an electric signal. In an optical cable laying construction method of the present invention, laying construction of the optical cable on site is carried out using the optical cable laying construction set (X).

Presented herein is a plurality of arrangements of cold plates having interior chambers. The interior chamber includes a plurality of fins with a first fin zone and a second fin zone. The cold plate further includes a first fluid inlet and a first fluid outlet. The cold plates can be connected such that each cold plate allows unidirectional flow or counter flow configurations. Unidirectional flow or counter flow cold plates can be arranged in rows and in combination of rows.

The photoelectric signal conversion and transmission device includes a photoelectric signal module and a fiber joint, matched and coupled together. A circuit board of the photoelectric signal module includes one or more connection bases. Light emission elements, light reception elements, and amplifiers are configured on a first coupling face of the connection based, and electrically connected by first and second wires. The fiber joint includes a number of fibers axially aligned with the light emission and reception elements. By having the light emission and reception elements and amplifiers configured on a same coupling face, their physical connection distance is reduced, thereby decreasing signal attenuation, enhancing signal transmission performance, and facilitating structural miniaturization.