Abstract: An electrical connector which controls cross talk and signal radiation. The electrical connector includes columns of contacts having signal contacts and ground contacts. Ground shields are positioned between the columns of contacts. The ground shields have planar members with mating ends and mounting ends. The planar members have surfaces which are configured to be electrically coupled to ground members on a mating connector. Voids are provided in the planar members. Mounting members extend from the mounting ends of the planar members. The mounting members are configured to cooperate with the ground contacts provided in the columns of contacts.

Abstract: A printed circuit board having signal contact receiving vias positioned in rows and ground contact receiving vias positioned in line with the signal contact receiving vias in the rows. Signal integrity vias are positioned between the signal contact receiving vias, between the ground contact receiving vias, and between respective signal contact receiving vias and respective ground contact receiving vias. The signal integrity vias form a ground fence which reduces cross talk in a foot print of a connector mated with the printed circuit board.

Abstract: A chiclet for a chiclet connector includes a conductor having a first end and a second end. A housing of the chiclet encloses and defines a housing interior. The conductor extends through the housing interior with the first and second ends of the conductor forming contacts projecting from the housing. The housing forms an electromagnetic shield electrically insulated from the conductor. A support of the chiclet corresponds in shape to the housing interior and is connected to the conductor for fixing the conductor within the housing.

Abstract: 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.

Abstract: A chiclet for a chiclet connector includes a conductor having a first end and a second end. A housing of the chiclet encloses and defines a housing interior. The conductor extends through the housing interior with the first and second ends of the conductor forming contacts projecting from the housing. The housing forms an electromagnetic shield electrically insulated from the conductor. A support of the chiclet corresponds in shape to the housing interior and is connected to the conductor for fixing the conductor within the housing.

Abstract: The output profile of light from a multimode optical fiber is determined using a geometrical optics approach where the rays launched into the fiber conform to LP-modes of the fiber. This output profile can then be employed as an input to a second fiber to calculate the transmission losses of a coupler that introduces various coupling inaccuracies, such as lateral offset, axial offset, and angular offset.

Abstract: An optical subassembly comprising: (a) an interposer having first and second opposing sides and defining at least one alignment aperture extending from said first opposing side to said second opposing side; (b) at least one fiber having a first optical axis disposed in said at least one alignment aperture; (c) at least one optical component mounted to said second opposing side having a second optical axis coincident with said first optical axis and defining an interface between said at least one optical component and said at least one optical component; and (d) a feedback component disposed on interposer within line-of-sight of said interface to receive at least a portion of uncoupled light emitted from said interface.

Abstract: 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.

Abstract: An optical subassembly comprising: (a) an interposer having first and second opposing sides and defining an alignment aperture extending from said first opposing side to said second opposing side, said interposer defining traces having contacts; (b) a fiber having a first optical axis, said fiber being held such that first optical axis is positioned essentially orthogonal to said first and second opposing sides; (c) at least one optical component mounted to said second opposing side and being electrically connected to at least a portion of said contacts, said at least one optical component having a second optical axis coincident with said first optical axis; and (d) a circuit board configured to receive said interposer such that said interposer is essentially orthogonal to said circuit board and said first optical axis is essentially parallel to said circuit board, said circuit board being electrically connected to at least a portion of said contacts.

Abstract: 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.

Abstract: 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.

Abstract: The output profile of light from a multimode optical fiber is determined using a geometrical optics approach where the rays launched into the fiber conform to LP-modes of the fiber. This output profile can then be employed as an input to a second fiber to calculate the transmission losses of a coupler that introduces various coupling inaccuracies, such as lateral offset, axial offset, and angular offset.

Abstract: An electrical connector includes a contact leadframe of unitary construction including first contacts extending to second contacts via corresponding leads, and an overmolded contact module housing formed over the leadframe, forming a connector module. The connector further includes the housing embedding the leads and surrounding the first contacts, the second contacts extending from the housing. The connector further includes a first surface of the first contacts in contact with the housing, and an opposed second surface of the first contacts being exposed. The connector includes a plurality of connector modules positioned in an aligned arrangement.

Abstract: The present disclosure relates to a fiber optic component including a ferrule having a distal end and a proximal end. The ferrule defines a fiber passage extending though the ferrule along a fiber passage axis in a proximal-to-distal orientation. The fiber optic component also includes an optical fiber structure affixed within the fiber passage. The optical fiber structure includes a beam expansion section optically coupled to a sacrificial section. The beam expansion section has a construction adapted to expand an optical beam from a first beam diameter to an enlarged second beam diameter. The sacrificial section is configured to receive the optical beam having the second beam diameter from the beam expansion section. The sacrificial section is positioned at the distal end of the ferrule and has a polished end face at the distal end of the ferrule. The sacrificial section has a core-less construction or has a core with a core diameter that is larger than the enlarged second beam diameter.

Abstract: An electrical connector includes a contact leadframe of unitary construction including first contacts extending to second contacts via corresponding leads, and an overmolded contact module housing formed over the leadframe, forming a connector module. The connector further includes the housing embedding the leads and surrounding the first contacts, the second contacts extending from the housing. The connector further includes a first surface of the first contacts in contact with the housing, and an opposed second surface of the first contacts being exposed. The connector includes a plurality of connector modules positioned in an aligned arrangement.

Abstract: The present disclosure relates to a fiber optic component including a ferrule having a distal end and a proximal end. The ferrule defines a fiber passage extending though the ferrule along a fiber passage axis in a proximal-to-distal orientation. The fiber optic component also includes an optical fiber structure affixed within the fiber passage. The optical fiber structure includes a beam expansion section optically coupled to a sacrificial section. The beam expansion section has a construction adapted to expand an optical beam from a first beam diameter to an enlarged second beam diameter. The sacrificial section is configured to receive the optical beam having the second beam diameter from the beam expansion section. The sacrificial section is positioned at the distal end of the ferrule and has a polished end face at the distal end of the ferrule. The sacrificial section has a core-less construction or has a core with a core diameter that is larger than the enlarged second beam diameter.

Abstract: An electrical connector includes a housing and plural contact modules stacked adjacent to each other and held by the housing. Each contact module includes a contact array, a dielectric holder, and lossy blocks. The contact array includes signal contacts and ground contacts arranged in alternating pairs along a length of a column. The dielectric holder surrounds and engages the signal and ground contacts along intermediate segments thereof to secure the signal and ground contacts in place. The lossy blocks are mounted to the intermediate segments of the ground contacts within the dielectric holder. Each lossy block is associated with a corresponding pair of ground contacts and engages at least one of the ground contacts in the pair. The lossy blocks are composed of a lossy material that has a greater loss tangent than a low loss material that forms the dielectric holder.

Abstract: A low-cost and mass producible carrier part for precise mounting of optical components such as an optical fiber and optical die and associated fabrication process.

Abstract: A GRIN fiber lens connection system particularly suited for high-power laser applications is disclosed. In one aspect, a GRIN fiber lens expanded beam system that is efficient over a wide spectral region, e.g., a range of about 200 nm, 300 nm or 400 nm, is disclosed for coupling one optical fiber (such as a single-mode fiber) to another. For example, a GRIN fiber lens expanded beam system is efficient over a range of wavelengths from about 400 nm to about 800 nm, from about 190 nm to about 390 nm, or from about 1270 nm to about 1650 nm. A method for designing such a coupling system is also disclosed. In another example, the cores of the GRIN fiber lenses are substantially devoid of germanium, and the cladding is doped with an element, such as fluorine, that lowers the refractive index of the cladding.

Abstract: A shield housing for a socket connector is disclosed. The shield housing comprises a first vertical wall, a second vertical wall opposite to the first vertical wall, and an interface wall connected between the first and second walls and having a receiving opening for receiving a plug connector, inner edges of the interface wall being provided with a plurality of elastic sheets bent and extending inwardly.