Abstract:
A pluggable connector that includes a connector housing having mating and loading ends and a longitudinal axis extending therebetween. The connector housing includes an insert cavity that opens to the mating end. The pluggable connector also includes a plug insert that is disposed within the insert cavity. The plug insert has an air core that extends in a direction along the longitudinal axis. The pluggable connector also including first and second differential pairs that extend along the longitudinal axis through the plug insert. Each of the first and second differential pairs includes two mating contacts that extend parallel to each other. The air core is located directly between the first and second differential pairs to control the electromagnetic coupling between the first and second differential pairs.
Abstract:
A flexible circuit is provided. The flexible circuit includes a circuit board mating end and a flexible body extending from the circuit board mating end. A conductive pathway extends through the flexible body to electrically couple circuit boards. A connector pad is positioned on the circuit board mating end. The conductive pathway electrically engages the connector pad. The connector pad is configured to electrically couple the flexible circuit to one of the circuit boards. A layer of uncured material extends between the connector pad and the conductive pathway. The layer of uncured material increases an impedance of the connector pad.
Abstract:
A flexible circuit configured to electrically couple circuit boards is provided. The flexible circuit includes opposite circuit board mating ends and a flexible body extending therebetween. Conductive pathways extend along the body of the flexible circuit to electrically couple the circuit boards. The flexible circuit also includes a temperature sensing circuit including leads having a distal end coupled to a temperature sensor and a temperature contact located proximate to one of circuit board mating ends. The temperature sensor is located at an intermediate position along the body between the circuit board mating ends. The temperature contact is configured to deliver temperature signals from the temperature sensor representative of a local flexible circuit temperature.
Abstract:
A connector assembly includes a housing and contacts. The housing is configured to mate with a mating connector. The contacts are in the housing and configured to electrically connect the connector assembly with the mating connector. The contacts are arranged in a coaxial signal contact pattern. The coaxial signal contact pattern includes a center signal contact surrounded by contacts electrically connected to an electrical ground in a manner to emulate a coaxial connection with the mating connector.
Abstract:
A mezzanine connector assembly is configured to electrically interconnect first and second circuit boards. The connector assembly includes a mounting body, a mating body, contacts and dielectric layers. The mounting body is configured to be mounted to the first circuit board. The mating body is disposed opposite of the mounting body and is configured to mate with the second circuit board. The mating body is separated from the mounting body by a separation gap along a vertical direction. The contacts extend between the mounting body and the mating body along the vertical direction. The contacts are configured to be coupled with the first and second circuit boards to electrically join the first and second circuit boards. The dielectric layers discretely surround corresponding ones of the contacts in the separation gap between the mounting body and the mating body. The dielectric layers are separated from one another by an air gap in the separation gap.
Abstract:
A memory module includes a circuit board having socket mating contacts at a socket interface and VRM contacts at a VRM interface. Memory devices are coupled to the circuit board. The memory devices are electrically connected to corresponding socket mating contacts and the memory devices are electrically connected to corresponding VRM contacts. A voltage regulator module is coupled to the circuit board at the VRM interface. The voltage regulator module is electrically connected to the VRM contacts.
Abstract:
A connector assembly includes a housing and substantially identical contacts. The housing is configured to mate with a mating connector. The contacts are arranged in a plurality of sets in the housing. The contacts are configured to electrically couple with the mating connector. Each set of contacts is arranged to communicate a different type of data signal with the mating connector. Optionally the contacts are formed as substantially identical pins. The different sets of contacts may concurrently communicate the different types of data signals.
Abstract:
The present invention involves a connector for inductively coupling to a multi-wire data bus utilizing a magnetic core and associated coil for inducing signals upon the bus and for sensing such signals on the bus. The connector includes a pair of magnetic members disposed on either side of the magnetic core for attenuating common mode energy generated within the connector at about the same frequency as that of the primary signal appearing on the data bus.
Abstract:
An interconnect assembly for interconnecting first and second electrical components includes a substrate having opposed first and second surfaces and a first array of contacts on the first surface for engaging corresponding elements on the first electrical component. The first array of contacts defines a compressible interface that mates with the first electrical component. The first array of contacts includes signal contacts transferring data signals across the compressible interface and the first array of contacts includes a combination of power contacts that jointly convey power across the compressible interface. The interconnect assembly also includes a second array of contacts on the second surface for engaging corresponding elements on the second electrical component. The second array of contacts having signal contacts electrically connected to the signal contact of the first array of contacts and power contacts electrically connected to the power contacts of the second array of contacts.
Abstract:
An interconnect assembly for interconnecting first and second electrical components includes a substrate having opposed first and second surfaces and a first array of contacts on the first surface for engaging corresponding elements on the first electrical component. The first array of contacts defines a compressible interface that mates with the first electrical component. The first array of contacts includes signal contacts transferring data signals across the compressible interface and the first array of contacts includes a combination of power contacts that jointly convey power across the compressible interface. The interconnect assembly also includes a second array of contacts on the second surface for engaging corresponding elements on the second electrical component. The second array of contacts having signal contacts electrically connected to the signal contact of the first array of contacts and power contacts electrically connected to the power contacts of the second array of contacts.