An electrical connector includes a housing, a plurality of contacts located in each wall of the housing and having grounding contacts and differential-pair contacts, and a grounding bar. The grounding bar includes a pair of lower spring fingers respectively contacting lower regions of the ground contacts in a transverse direction, and a pair of upper spring fingers respectively contacting upper regions of the ground contacts in the transverse direction, an upper transverse bar linked between the pair of upper spring fingers along a longitudinal direction, a lower transverse bar linked between the pair of lower spring fingers along the longitudinal direction, the pair of upper spring fingers extend upwardly from the lower transverse bar and a transverse base having retaining device attached to a lower portion of the housing. The pair of lower spring fingers upwardly extend from the transverse base.

A contact module includes a leadframe having signal contacts arranged in pairs. Each signal contact includes a lead having sides extending between inner and outer edges. The contact module includes a dielectric frame supporting the leadframe having a first side and a second side with windows extending through the dielectric frame between the first side and the second side. The windows exposing to air the sides, the inner edges and the outer edges of the corresponding leads along a majority of lengths of the leads. The contact module includes a shield structure having a first ground shield at the first side and a second ground shield at the second side to provide electrical shielding for the signal contacts.

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.

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 modular electrical connector with modular components suitable for assembly into a right angle connector may also be used in forming an orthogonal connector or connector in other desired configurations. The connector modules may be configured through the user of extender modules. Those connector modules may be held together as a right angle connector with a front housing portion, which, in some embodiments, may be shaped differently depending on whether the connector modules are used to form a right angle connector or an orthogonal connector. When designed to form an orthogonal connector, the extender modules may interlock into subarrays, which may be held to other connector components through the use of an extender shell. The mating contact portions on the extender modules may be such that a right angle connector, similarly made with connector modules, may directly mate with the orthogonal connector.

A modular electrical connector with modular components suitable for assembly into a right angle connector may also be used in forming an orthogonal connector or connector in other desired configurations. The connector modules may be configured through the user of extender modules. Those connector modules may be held together as a right angle connector with a front housing portion, which, in some embodiments, may be shaped differently depending on whether the connector modules are used to form a right angle connector or an orthogonal connector. When designed to form an orthogonal connector, the extender modules may interlock into subarrays, which may be held to other connector components through the use of an extender shell. The mating contact portions on the extender modules may be such that a right angle connector, similarly made with connector modules, may directly mate with the orthogonal connector.

An electrical connector is used to electrically connect a first component to a second component. The electrical connector includes multiple terminals. Each terminal has a connecting portion, a first conduction portion and a second conduction portion. The first conduction portion extends forward from the connecting portion to be electrically connected to the first component, and has a first contact point in contact with the first component. The second conduction portion extends backward from the connecting portion to be electrically connected to the second component, and has a second contact point in contact with the second component. A distance between the first contact point and the second contact point is 7.460.4 mm.

A cabled receptacle connector includes a receptacle housing having a cavity extending between a front and a rear and having a mating slot receiving a pluggable module. A cable assembly is received in the cavity having wafers provided at an end of a cable bundle. Each wafer has a dielectric frame holding a wafer lead frame having signal contacts and ground contacts. The signal and ground contacts have terminating ends terminated to corresponding cables and mating ends received in the mating slot for mating with the pluggable module. Each wafer has a ground bus frame electrically coupled to each of the ground contacts to electrically common each of the ground contacts. The ground bus includes ground beams having mounting arms coupled to the dielectric frame and mating pads coupled to corresponding ground contacts. The mating ends of the signal contacts and the ground contacts are arranged in multiple rows for interfacing with the pluggable module.

An electrical connector includes a first set of conductors, a first overmolding in physical contact with a body portion of each of the first set of conductors, a second set of conductors, a second overmolding in physical contact with the body portion of each of the second set of conductors, and a spacer in contact with the first overmolding and the second overmolding. A gap is present between the spacer and at least one of the first set of conductors and a gap between the spacer and at least one of the second set of conductors.

An electrical connector includes a first set of conductors, a first overmolding in physical contact with a body portion of each of the first set of conductors, a second set of conductors, a second overmolding in physical contact with the body portion of each of the second set of conductors, and a spacer in contact with the first overmolding and the second overmolding. A gap is present between the spacer and at least one of the first set of conductors and a gap between the spacer and at least one of the second set of conductors.