Abstract: An electrical connector includes a dielectric housing, a plurality of electrical signal contacts carried by the dielectric housing, and a ground plate carried by the dielectric housing. The electrical signal contacts are arranged along a first plane, wherein the signal contacts define signal pairs such that a respective gap is disposed between adjacent signal pairs. The signal contacts further define respective mating and mounting ends. The ground plate includes a ground plate body oriented in a second plane that is substantially parallel to the first plane and offset from the first plane. The ground plate body defines first and second opposed surfaces. The ground plate includes at least one rib that defines first and second opposed surfaces, wherein the first surface of the rib projects from the first surface of the ground plate body in a direction toward the gap, and the second surface is recessed into the second surface of the ground plate body.

Abstract: An electrical connector lock can include a mounting member configured to attach to a substrate. The electrical connector lock can also include force cancellation member that cancels forces generated on an electrical component by a mated component.

Abstract: An electrical connector include a movable hold down member that is configured to receive a fastener so as to secure the electrical connector to an underlying substrate to which the electrical connector is mounted.

Abstract: A power connector can include a dielectric connector housing and electrical contacts that are supported by the housing. The electrical contacts can each include first and second contact bodies. The first contact body can include a first contact blade and the second contact body can include a second contact blade that can define a mating portion of the electrical contact. The mating portion can be configured to mate with a complementary power connector along a mating direction so as to establish an electrical connection between the power connector and the complementary power connector. The contact blades can be configured slide with respect to each other along the mating direction.

Abstract: Electrical connectors that are mating compatible with the MicroTCA® standard and configured to be mounted to an underlying substrate are provided. Certain of the electrical connectors can be configured to be mounted to a substrate configured in accordance with the MicroTCA® press fit footprint. Additionally, electrical connectors that are mating compatible with the MicroTCA® standard and configured to be mounted to respective alternative footprints, and substrates configured in accordance with the respective alternative footprints are provided. The disclosed electrical connectors and corresponding substrate footprints can operate to transmit data at speed up to and in excess of 25 Gigabits per second.