A multi-fiber ferrule has lenses that have different prescriptions to disperse the light emitted from the multi-fiber ferrule. Alternatively, the lens for each individual optical fiber can be moved relative to the optical fiber or the optical fiber opening in the multi-fiber ferrule to cause the laser beam exiting the multi-fiber ferrule to be redirected into a structure that absorbs or blocks the laser.

A light source device and an electronic apparatus are provided. The light source device includes a substrate, an electrode layer and a surrounding frame disposed on the substrate, a light emitter and a light detector mounted on the electrode layer and located inside of the surrounding frame, and a light permeable member disposed on the surrounding frame and covering the light emitter and the light detector. When the light emitter receives a predetermined current so as to emit an invisible light toward the light permeable member, the light detector receives a reflected part of the invisible light to generate an initial photocurrent. When the light emitter receives a manipulation current so that a detection photocurrent generated from the light detector is less than a first proportion of the initial photocurrent or greater than a second proportion of the initial photocurrent, the light emitter stops receiving the manipulation current.

An adaptor with a built-in shutter member for optical connector including a body, a shutter, and an elastic member is provided. The body has a receiving space. The shutter is movably assembled to the body to shield or expose the receiving space. An optical connector is suited for pushing away the shutter to enter the receiving space to be connected to the body. The shutter has a step structure such that a gap is maintained between the shutter and the optical connector. The elastic member is disposed in the body and located on a moving path of the shutter. The shutter deforms the elastic member when the optical connector pushes away the shutter, and the elastic member drives the shutter to be restored when the optical connector leaves the receiving space.

The present disclosure provides pluggable optical modules that are prevented from reaching potentially dangerous temperatures when a fiber optic connector is not present and engaged with the associated module housing. Further, the present disclosure provides fiber optic connectors and/or pluggable optical modules that incorporate a port heat shield external to the associated face plate when the pluggable optical modules and fiber optic connectors are engaged, thereby preventing a user from contacting potentially hot and dangerous metallic surfaces of the module housings, as well as providing access for cooling air flow. The solutions presented herein are equally applicable to fixed optical ports and connectors as well.

A mounting clip can be placed and secured over the exterior surfaces of a package of an integrated optical assembly. The mounting clip includes a top panel, end clips that curl and extend down from end edges of the top panel, an interference tab that extends up from the top panel, and cap clips that curl and extend up from the top panel. The mounting clip is dimensioned such that bends in the end clips press and secure against exterior side surfaces of the package of the integrated assembly. Thus, the mounting clip can be secured to the package of the integrated assembly using an interference or friction fit. A cap on a fiber optic cable that extends from the package can be curled around and secured between the interference tab and cap clips of the mounting clip to secure it during surface mounting.

An optical connector includes a core block, a flexible wiring board, an optical device array, a drive circuit, and a housing. The core block has a plurality of faces. The flexible wiring board has an external connection terminal, a first area arranged on a first face of the core block, and a second area arranged on a second face of the core block. The optical device array is mounted on the first area of the flexible wiring board and includes at least one group of a plurality of optical devices for transmission and a plurality of optical devices for reception arranged. The drive circuit is mounted on the second area of the flexible wiring board and drives the optical device array. The housing stores the core block, the optical device array, and the drive circuit such that the external connection terminal of the flexible wiring board is arranged outside the housing.

A plug-in connection for the transmission of electric current having a male connector and a female connector, wherein the male connector includes a plug-in extension having electrical contacts, and the female connector includes a plug-in extension receptacle having electrical mating contacts, and at least one projection is arranged on one jacket wall, and the other of these jacket walls incorporates at least one receptacle slot which matches the projection. The plug-in extension, with the projection and the receptacle slot in an undamaged state, can only be inserted into the plug-in extension receptacle from an unambiguously defined plug-in position. The male connector, in the plug-in extension interior, additionally incorporates at least one moulding, and the female connector, in the plug-in extension receptacle interior, additionally incorporates at least one mating moulding, and the moulding and the mating moulding, in combination, constitute a stop mechanism for the prevention of any electrical contacting of the electrical contacts with the electrical mating contacts.

The present disclosure relates to connector ports with shutters configured to inhibit dust intrusion by including peripheral regions that oppose undercut portions of the connector port when the shutter is closed. The present disclosure also relates to fiber optic connectors having latching configurations with double latches for retaining the fiber optic connectors in connector ports. The present disclosure also relates to a fiber optic connector including a plurality of stacked fiber carrier modules. The present disclosure also relates to a fiber optic connector including a connector body and a rear connector piece that is secured to the connector body by a snap-fit connection. The rear connector piece can be configured for attachment to a fiber optic cable. The rear connector piece can be secured to the connector body by a snap-fit connection. The rear connector piece can have a snap-fit interface compatible with a number of different styles or types of connector bodies to promote manufacturing efficiency.

An optical fiber connector includes a main unit and a housing unit. The main unit includes a boot and a connector module that has a rear part connected to a front end of the boot, and a front coupling end distal from the boot. The housing unit includes a sliding sleeve sleeved slidably around the connector module, and a light blocking member pivotally connected to the sliding sleeve. The sliding sleeve is operable between a light blocking position, where the light blocking member blocks light from the front coupling end, and a fiber coupling position, where the light blocking member rotates relative to the sliding sleeve and allows the front coupling end to be exposed from the sliding sleeve.

A fiber optic adapter is disclosed by the present disclosure, and belongs to the technical field of fiber optic adapter. The fiber optic adapter includes at least two ports for connecting to a fiber optic connector. Each of the ports is provided with a light shielding plate. An elastic member is shared between every two adjacent light shielding plates, and configured to support the every two adjacent light shielding plates to shield ports corresponding to the every two adjacent light shielding plates. In the present disclosure, the elastic member is shared between the two light shielding plates, so that the assembly efficiency is improved, thereby solving the problem that the assembly of the elastic tabs of the existing fiber optic adapter is relatively cumbersome.