An information handling system may include a printed circuit board and a plurality of connectors each electrically and mechanically coupled to the printed circuit board, each connector of the plurality of connectors configured to receive a respective modular information handling resource in order to electrically couple, via electrically-conductive pins of such connector, the respective modular information handling resource to the printed circuit board. Each connector may include a body comprising electrically non-conductive material and including a receptacle formed therein for receiving a mating edge connector of the respective modular information handling resource, a bus bar comprising electrically conductive material, other than the electrically-conductive pins of such connector, disposed within or upon the body and extending through at least a portion of the body, and an electrical termination electrically coupled to the bus bar.

A modular die cast enclosure comprising a top section with a top mid-plane and a bottom section with a bottom mid-plane and an internal bottom cover. The bottom section having one or more of a first type of connectors. The top section having one or more of a second type of connectors on. The internal bottom cover having one or more of a third type of connectors. Wherein said first type of connectors couple with said second type of connectors when the top section is placed on the bottom section and allow to electrically connect said top and bottom sections via said third type of connectors.

A connection assembly, including: a first connector having a first end and a second end, and a first surface extending between the first end and the second end, the first connector including press fit pins extending away from the first surface, each of the press fit pins including: a rod portion; a connecting portion having a first shape; a second connector having a first end and a second end, including: a dielectric carrier having a first surface extending between the first end and the second end of the second connector, receptacles positioned within the first surface of the dielectric carrier, each of the receptacles including: a cylindrical region, a tapered region having a second shape that corresponds to the first shape of the connection portion, wherein, when the first connector is coupled to the second connector, the press fit pins are positioned within respective receptacles of the receptacles.

A memory module socket, including a first member extending between a first end and a second end of the socket, the second end of the socket opposite to the first end of the socket, the first member positioned along a first side of the socket, the first member including: a plurality of first contact pins, each of the first contact pins including a first contact point and a second contact point; a plurality of first resistive coatings connecting two or more of the first contact pins to define first groupings of contact pins; a plurality of first ribs separating each of the first groupings of first contact pins; wherein when the first contact pins are in a first position, the second contact points of the first contact pins are in contact with respective first resistive coatings to complete a termination to ground.

An orthogonal electrical connector system includes vertical electrical connectors that are configured to be mated to each other so as to place respective pluralities of first and second substrates that are oriented orthogonal to each other in data communication with each other through the mated electrical connectors. Other connector systems are also disclosed.

A miniaturized card edge connector providing reliable operation. A connector may have a reinforcing member comprising a main body, a first connector engaging portion and a second connector engaging portion. The first connector engaging portion and the second connector engaging portion extend from the main body in a first vertical direction and are spaced apart in a transverse direction. The first connector engaging portion and the second connector engaging portion are configured to be engaged to both sides of a card slot of the electrical connector. The reinforcing member may effectively protect the insulating body of the electrical connector against deformation or even damage. The reinforcing member can strengthen the connection between the electrical connector and the circuit board to ensure their stable connection. Since the reinforcing member itself is multifunctional and is convenient for mounting, the assembly period may be shortened and the product cost may be lowered.

This application provides a board-level architecture and a communications device. The board-level architecture includes a support board, a switch board, and a press fit component. The press fit component includes a cable, a first connector component press-fitted on a side edge of the support board, and a second press fit cable connector press-fitted on a side edge of the switch board. The first connector component includes a first press fit cable connector and a pluggable connector that is electrically connected to the first press fit cable connector, and the pluggable connector is farther from the support board than the first press fit cable connector. The first press fit cable connector is connected to the second press fit cable connector through the cable.

The present invention discloses a holder carrying thereon a sensor to measure a physiological signal of an analyte in a biological fluid, wherein the sensor has a signal detection end and a signal output end, and the holder includes an implantation hole being a channel for implanting the sensor and containing a part of the sensor, a fixing indentation containing the sensor, a filler disposed in the fixing indentation to retain the sensor in the holder, and a blocking element disposed between the implantation hole and the fixing indentation to hold the sensor in the holder and restrict the filler in the fixing indentation.

Electrical connectors for very high speed signals, including signals at or above 112 Gbps. Effectiveness of shielding along the signal paths through the mating electrical connectors may be enhanced through the use of one or more techniques, including enabling two-sided shielding, connections between shield members and between shield members and grounded structures of printed circuit boards to which the connectors are mounted, and selective positioning of lossy material. Such techniques may be simply and reliably implemented in high density connector using one or more techniques. An electrical connector may include core members held by a housing together with leadframe assemblies attached to the core members. The core members may include features that would be difficult to mold in a housing and may include both shields and lossy materials in locations that would be difficult to incorporate in a leadframe assembly.

A card edge connector for transmitting signal and power simultaneously. The connector has two or more types of conductors held by a housing. First and second types of conductors are configured for transmitting signal and power, respectively. The housing has a slot for receiving a mating component. The housing has first and second types of grooves for holding the first and second types of conductors, respectively, such that the conductors can sustain a similar amount of force generated when mating with the mating component. The conductors have mating ends with contact portions curving into the slot and mounting ends opposite the mating ends and extending out of the housing. The mating and mounting ends of the first and second types of conductors are configured such that they can be deflected by the mating component simultaneously and mounted to a printed circuit board using a same process.