A connector includes a connector body and a terminal attached to the connector body, the connector being fitted with a counterpart connector, the connector body includes a recess being fitted with a counterpart connector body of the counterpart connector and side walls extending in a longitudinal direction of the connector body, the side walls defining both sides of the recess. The terminal includes a plurality of terminals disposed along each of the side walls, and the plurality of terminals disposed along each of the side walls include one high frequency terminal and ground terminals disposed on both sides of the high frequency terminal. In plan view, a straight line connecting high frequency terminals disposed along both the side walls is inclined with respect to a center line of the connector body in a width direction, and a shield plate of the counterpart connector extends along the center line.

An electrical connector has a row of signal contacts, and a ground shield disposed inwardly from the signal contacts. Each of the signal and ground contacts has a first segment and a second segment. Each first segment defines a mounting end that can mount to a first electrical component, and each second segment defines a mating end that can mate with a second electrical component. The first and second segments of each signal contact and the ground contact are angularly offset from one another so as to define an angle of between 75 degrees and 105 degrees between the first and second segments. The first and second segments of each signal contact and the ground contact can be coupled to one another to define the angle. Alternatively, the signal and ground contacts can be bent along a common bend line that intersects the signal contacts and the ground contact.

An electrical connector has a row of signal contacts, and a ground shield disposed inwardly from the signal contacts. Each of the signal and ground contacts has a first segment and a second segment. Each first segment defines a mounting end that can mount to a first electrical component, and each second segment defines a mating end that can mate with a second electrical component. The first and second segments of each signal contact and the ground contact are angularly offset from one another so as to define an angle of between 75 degrees and 105 degrees between the first and second segments. The first and second segments of each signal contact and the ground contact can be coupled to one another to define the angle. Alternatively, the signal and ground contacts can be bent along a common bend line that intersects the signal contacts and the ground contact.

A wafer includes a number of conductive terminals and an insulating frame. The conductive terminals include differential signal terminals, a first ground terminal and a second ground terminal. Each conductive terminal includes a connection portion and a contact portion. The connection portions of the differential signal terminals, the first ground terminal and the second ground terminal are located in a first plane. The first ground terminal includes a first torsion portion and the second ground terminal includes a second torsion portion. The contact portion of the first ground terminal and the contact portion of the second ground terminal are both perpendicular to the first plane. This present disclosure can provide better shielding effect, reduce crosstalk and improve the quality of signal transmission. In addition, the present disclosure also relates to a backplane connector having the wafer.

A wafer includes a number of conductive terminals and an insulating frame. The conductive terminals include differential signal terminals, a first ground terminal and a second ground terminal. Each conductive terminal includes a connection portion and a contact portion. The connection portions of the differential signal terminals, the first ground terminal and the second ground terminal are located in a first plane. The first ground terminal includes a first torsion portion and the second ground terminal includes a second torsion portion. The contact portion of the first ground terminal and the contact portion of the second ground terminal are both perpendicular to the first plane. This present disclosure can provide better shielding effect, reduce crosstalk and improve the quality of signal transmission. In addition, the present disclosure also relates to a backplane connector having the wafer.

An electrical connector assembly can include a plug connector and a receptacle connector that can mate together. Conductive communication between the plug and receptacle connectors is established by mating signals terminals and mating ground terminals contained in terminal subassemblies accommodated in each connector. To align and support the signal and ground terminals, the terminals may be part of a terminal wafer and the terminal subassembly can be assembled from one or more wafers. The terminal wafer may include grounding features to improve the electrical characteristics and data transmission through the electrical connector assembly.

An electrical connector assembly can include a plug connector and a receptacle connector that can mate together. Conductive communication between the plug and receptacle connectors is established by mating signals terminals and mating ground terminals contained in terminal subassemblies accommodated in each connector. To align and support the signal and ground terminals, the terminals may be part of a terminal wafer and the terminal subassembly can be assembled from one or more wafers. The terminal wafer may include grounding features to improve the electrical characteristics and data transmission through the electrical connector assembly.

An electrical connector with improved high frequency performance. The connector has conductive elements, forming both signal and ground conductors, that have multiple points of contact distributed along an elongated dimension. The ground conductors may be formed with multiple beams of different length. The signal conductors may be formed with multiple contact regions on a single beam, with different characteristics. Signal conductors may have beams that are jogged to provide both a desired impedance and mating contact pitch. Additionally, electromagnetic radiation, inside and/or outside the connector, may be shaped with an insert electrically connecting multiple ground structures and/or a contact feature coupling ground conductors to a stiffener. The conductive elements in different columns may be shaped differently to reduce crosstalk.

An electrical connector with improved high frequency performance. The connector has conductive elements, forming both signal and ground conductors, that have multiple points of contact distributed along an elongated dimension. The ground conductors may be formed with multiple beams of different length. The signal conductors may be formed with multiple contact regions on a single beam, with different characteristics. Signal conductors may have beams that are jogged to provide both a desired impedance and mating contact pitch. Additionally, electromagnetic radiation, inside and/or outside the connector, may be shaped with an insert electrically connecting multiple ground structures and/or a contact feature coupling ground conductors to a stiffener. The conductive elements in different columns may be shaped differently to reduce crosstalk.

A connector for use with high speed signals. The connector may include lead frame assemblies in a connector housing. A lead frame assembly may include signal conductive elements and ground conductive elements disposed in a repeating pattern, and one or more corrugated sheets attached to the ground conductive elements. The corrugated sheets may extend more than half of the length of the signal conductive elements. Valleys of the corrugated sheets may be welded to the ground conductive elements with line welds. The line welds may extend over a large percentage of the length of the conductive elements. Such a configuration enables accurately and repeatedly establishing signal to ground spacing and therefore promotes high signal integrity, even for miniaturized connectors. Such a connector may be used to meet signal integrity requirements in connectors designed for 112 GBps and beyond.