An optical connector for coupling to a counter-connector mechanically and optically, a portion of an optical transmission line transmitting an optical signal being disposed in the optical connector, includes: a first outer case through which the optical transmission line is inserted and that covers an incidence end or an emitting end of an optical signal through the optical transmission line; a cover plate that is permeable to an optical signal and seals a tip end side coupled to the counter-connector in the first outer case; and a coating film made of amorphous carbon that is disposed on a surface on the tip end side of the cover plate.

A hybrid plug connector including an insulative housing defining a cavity to receive an optical fiber assembly therein, and a plurality of passageways to receive a plurality of terminals therein. A printed circuit board is located behind the terminals and connected to the terminals. An electrical cable is mounted to a rear portion of the circuit board. The whole optical fiber assembly is received within the housing and is somewhat back and forth moveable along a front-to-back direction for buffering for compliantly coupling with another optical fiber assembly built within the complementary receptacle connector when the plug connector is inserted into the complementary receptacle connector. An attachment shows the manufacturing process.

A hybrid fiber optic/electrical connector including a connector body (111) having a front end (112) and a back end (113); a ferrule (510) mounted at the front end of the connector body, the ferrule including a depth that extends from a front end (171) to a rear end (173) of the ferrule; a spring (129) for biasing the ferrule (510) in a forward direction relative to the connector body (111); a plurality of optical fibers (175) supported by the ferrule (510), the optical fibers having end faces (106) accessible at the front end (171) of the ferrule; and electrical conductors (179) supported by the ferrule (510), the electrical conductors including spring-loaded contacts (163) accessible at the front end (171) of the ferrule.

It is an object of the present invention to accurately maintain a positional relationship between a lens held in a holding member and an optical fiber without requiring any complicated operation. The invention includes a holder (11), at one end of which a housing section (11c) that houses a ball lens (12) is formed and at the other end of which an insertion hole (11a) for inserting an optical fiber (13) is formed, and a magnet (14) provided outside in a direction crossing a housing direction of the ball lens at the one end of the holder, in which the magnet generates an attracting force for aligning a center of the ball lens with a center of an optical element provided in a coupling target.

A first connector for a medical instrument has one or more first channels extending through a first surface, and terminating at respective ends. A second connector has opposing second channels for coupling with the first channels. A first power transfer element is mounted on the first connector, and defines a first cross-sectional shape that encompasses at least one of the one or more first channels and has a first central axis extending through the first surface. A second power transfer element on the second connector defines a second cross-sectional shape that encompasses at least one of the one or more second channels and has a second central axis extending through the second surface. The first power transfer element may instead be on a side surface of the first connector, and may couple with a paired element on a receptacle or extension of the second connector.

A system includes a substrate on which a data processor and a connector block are mounted. The connector block has a first array of electrical connectors on a first surface, and a second array of electrical conducts on a second surface that is oriented at an angle between 45° to 135° relative to a main surface of the substrate. At least a portion of the first array of electrical connectors are electrically coupled to the data processor, and the second array of electrical contacts are electrically connected to the electrical contacts of a pluggable module. The pluggable module includes 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.

There is provided a cable including at least one optical fiber cable, at least two electrical cables provided so as to sandwich the optical fiber cable, and plugs positioned at both ends and each having an electrical contact part connected to each of the electrical cables.

Circuits, apparatus, and methods that provide a connector system that can supply both power and data to a mobile computing or other type of device using a single connection. Further examples also provide a power and data adapter that can provide power and data to a mobile computing device using a single cable. Further examples provide an easy disengagement when a cable connected to the connector is pulled. One such example provides a magnetic connector that uncouples without binding when its cord is pulled. Another example prevents power from being provided at a connector insert until the connector insert is placed in a connector receptacle.

A cable connector, including a housing having a base and a lip, which surrounds the base and defines an aperture configured to receive a mating plug. The cable connector also includes a plurality of electrical contacts enclosed by the housing and configured to convey electrical signals, the electrical contacts having respective first proximal and first distal ends, the first proximal ends being implanted in the base so that the first distal ends are recessed within the aperture at a first distance from the base. The cable connector additionally includes one or more optical fiber terminals containing end portions of respective optical fibers configured to convey optical signals and having respective second proximal and second distal ends, the second proximal ends being implanted in the base so that the second distal ends are recessed within the aperture at a second distance from the base, which is greater than the first distance.

A cage assembly comprises a cage, at least one heat sink, at least one clip and at least one light guide. The cage comprises a front end, a rear end, a top wall positioned between the front end and the rear end and a rear wall positioned at the rear end, the cage is formed with at least one port, the port extends from the front end to the rear end. The heat sink is provided on the top wall of the cage and corresponds to one port. The clip comprises a frame engaged with the top wall and fixing the heat sink and a holding piece extending upwardly from the frame. The light guide has a front section and a rear section, the front section is formed with a first post extending rearwardly, the rear section is formed with two second posts respectively extending forwardly, the first post is inserted into a first hole formed to the holding piece of the clip along a front-to-rear direction, the two second posts are respectively inserted into two second holes formed to the rear wall of the cage along a rear-to-front direction.