A pluggable optical module, including: a pluggable module unit including an optical connector disposed at a front end portion thereof and an electrical connector disposed at a rear bottom portion thereof, wherein the optical connector is configured to be optically coupled to an optical fiber, and wherein the electrical connector is configured to be electrically coupled to an electrical connector disposed on an electrical board. Optionally, the pluggable module unit includes a pluggable module adapter secured to a pluggable module body. The electrical connector is then disposed at a rear bottom portion of the pluggable module adapter. A pluggable optical module aggregator, including: a housing; an electrical board; a plurality of electrical connectors and a bulk electrical connector consolidating and terminating the plurality of electrical connectors and accessible from the exterior of the housing; and a plurality of optical connectors and a bulk optical connector consolidating and terminating the plurality of optical connectors and accessible from the exterior of the housing.

A fiber connector, comprising a housing having a chamber extending in a lengthwise direction from a first end configured to receive a fiber to a second end configured to connect the fiber to a laser processing head and a channel disposed on an exterior surface of the chamber, the channel comprising a double helical structure.

A pluggable optical module, including: a pluggable module unit including an optical connector disposed at a front end portion thereof and an electrical connector disposed at a rear bottom portion thereof, wherein the optical connector is configured to be optically coupled to an optical fiber, and wherein the electrical connector is configured to be electrically coupled to an electrical connector disposed on an electrical board. Optionally, the pluggable module unit includes a pluggable module adapter secured to a pluggable module body. The electrical connector is then disposed at a rear bottom portion of the pluggable module adapter. A pluggable optical module aggregator, including: a housing; an electrical board; a plurality of electrical connectors and a bulk electrical connector consolidating and terminating the plurality of electrical connectors and accessible from the exterior of the housing; and a plurality of optical connectors and a bulk optical connector consolidating and terminating the plurality of optical connectors and accessible from the exterior of the housing.

Nano-particle based mode strippers for removing undesirable laser energy for laser systems. Nano-particle mode strippers having matched indices of refraction to the outer cladding remove cladding light converting it into heat. There are provided fibers having evanescent mode strippers having annular outer cores and claddings.

An optical adapter includes: a housing having a plurality of openings on each of opposite end surfaces thereof; a plurality of ports formed in parallel with each other inside the housing and each extending to form one of the openings on each of the opposite ends surfaces, an optical connector being inserted into each of the openings; and a shutter part installed at each of the ports such that when the optical connector is inserted into an opening of one end of the port, the shutter part leans back to a retreat position that passes light emitted from the optical connector inserted into an opening of another end of the port, when the optical connector is pulled out of the opening of the one end of the port, the shutter part is raised up from the retreat position to a blocking position that blocks the emitted light.

Embodiments include an optical fiber cable comprising a length extending between a first end and a second end, a central cooling tube, a plurality of optical fibers disposed radially around the cooling tube, each optical fiber comprising a fiber core and a cladding disposed around the fiber core, an outer protective cover, and an inner thermal filler disposed between the outer protective cover and the central cooling tube and surrounding each of the optical fibers, wherein each of the central cooling tube, the outer protective cover, the inner thermal filler, and the plurality of optical fibers extend the length of the cable. Various systems and methods for removing imperfections from individual optical fibers and for distributing power across long distances using the optical fiber cable are also provided.

An optical adapter includes: a housing having a plurality of openings on each of opposite end surfaces thereof; a plurality of ports formed in parallel with each other inside the housing and each extending to form one of the openings on each of the opposite ends surfaces, an optical connector being inserted into each of the openings; and a shutter part installed at each of the ports such that when the optical connector is inserted into an opening of one end of the port, the shutter part leans back to a retreat position that passes light emitted from the optical connector inserted into an opening of another end of the port, when the optical connector is pulled out of the opening of the one end of the port, the shutter part is raised up from the retreat position to a blocking position that blocks the emitted light.

In an optoelectrical connector including two connectors to be interconnected, each having at least one optical connection part and at least two electrical connection parts, the electrical connection parts of one of the connectors are pins and the electrical connection parts of the other connector are spring contacts. The connector having the spring contacts includes, before the spring contacts, positioning holes in which the pins are to be inserted. The tips of the pins come into contact with the spring contacts to make electrical connection. The bases of the pins fit in the positioning holes to perform positioning for optical connection. The optoelectrical connector can be smaller, lighter, and thinner.

An optoelectronic assembly connectorizing light through an optical fiber. A housing includes an axially extending cavity. A transparent window is located at a first end of the cavity. A termination part is located at a second end of the cavity. The cavity forms a cooling chamber being fed by a flowing coolant surrounding an envelope surface of the optical fiber. The optical fiber is in optical contact with the window and extends out of the assembly through the termination part. The optical fiber is fixed in the termination part with a guiding glue.

Disclosed is an optical connector ferrule including a main body portion having inside a plurality of optical paths that are parallel that are to each other; and a reinforcing member having a face parallel to an alignment direction of the plurality of the optical paths and having a linear expansion coefficient that is smaller than the linear expansion coefficient of the main body portion, wherein the reinforcing member has on a face of the optical path side thereof at least two limiting portions each having a face that limits an expansion and a contraction of the main body portion in the arrangement direction, the limiting portions being spaced apart in the arrangement direction.