A terminal fitting is provided with a tubular connecting portion and a deflectable and deformable resilient contact portion arranged in the connecting portion. The connecting portion includes a bead extending in a front-rear direction and projecting inward toward a contact point of the resilient contact portion on a base wall portion facing the contact point. An outer surface of the base wall portion includes recesses recessed inwardly in both front and rear end parts of the bead, and a shorting terminal facing portion located outwardly of bottoms of the recesses between the both front and rear end parts of the bead.

A terminal of a connector has a receiving portion, a first supporting portion which is resiliently deformable and extends from the receiving portion, a contact portion supported by the first supporting portion, a second supporting portion extending from the contact portion and an abutment portion supported by the second supporting portion. In a connection process of the connector and a mating connector, the abutment portion of the terminal begins to be brought into contact with the receiving portion at a first position on the receiving portion, and it is slid on the receiving portion until the abutment portion reaches a second position. The contact portion is brought into contact with a mating terminal when the connector is connected to the mating connector.

A terminal of a connector has a receiving portion, a first supporting portion which is resiliently deformable and extends from the receiving portion, a contact portion supported by the first supporting portion, a second supporting portion extending from the contact portion and an abutment portion supported by the second supporting portion. In a connection process of the connector and a mating connector, the abutment portion of the terminal begins to be brought into contact with the receiving portion at a first position on the receiving portion, and it is slid on the receiving portion until the abutment portion reaches a second position. The contact portion is brought into contact with a mating terminal when the connector is connected to the mating connector.

A connector cable includes a plurality of contacts placed in a row and a plurality of cables connected to the plurality of contacts. The plurality of cables includes at least three pairs of high-speed differential signal lines for transmitting high-speed differential signals, at least one non-high-speed differential signal line for transmitting a non-high-speed differential signal, and a plurality of ground terminals. The plurality of ground terminals is allocated to contacts on both ends among the plurality of contacts and a contact between two pairs of high-speed differential signal lines or between one pair of high-speed differential signal lines and one non-high-speed differential signal line to limit the number of consecutive pairs of high-speed differential signal lines to two.

A connector cable includes a plurality of contacts placed in a row and a plurality of cables connected to the plurality of contacts. The plurality of cables includes at least three pairs of high-speed differential signal lines for transmitting high-speed differential signals, at least one non-high-speed differential signal line for transmitting a non-high-speed differential signal, and a plurality of ground terminals. The plurality of ground terminals is allocated to contacts on both ends among the plurality of contacts and a contact between two pairs of high-speed differential signal lines or between one pair of high-speed differential signal lines and one non-high-speed differential signal line to limit the number of consecutive pairs of high-speed differential signal lines to two.

A method of making an electrical connector which includes an insulative housing having a tongue with two opposite surfaces and plural contacts with contacting portions exposed to the two opposite surfaces of the tongue is characterized by the steps of: forming the plurality of contacts from a single contact carrier to have one group of contacts thereof each with a respective contacting portion connected to a first carrier strip and the other group of contacts thereof each with a respective contacting portion connected to a second carrier strip situated beside the first carrier strip; insert-molding the plurality of contacts with an insulator to form the insulative housing while exposing front ends of the plurality of contacts; and severing the first carrier strip and the second carrier strip from the front ends of the plurality of contacts.

An electrical connector assembly for electrically and mechanically connecting a component to a power source is disclosed. The connector assembly includes a male terminal with side walls defining a receiver. The side wall includes a contact arm that extends across an aperture in the side wall. The assembly also includes an internal spring member dimensioned to reside within the receiver of the male terminal. The spring member has at least one spring arm that extends from a base portion. The assembly further includes a female terminal with a receptacle dimensioned to receive both the male terminal and the spring member residing within the receiver of the male connector to define a connected position. In the connected position, the spring arm exerts an outwardly directed biasing force on the contact arm of the male terminal to outwardly displace it into engagement with an inner surface of the receptacle to ensure connectivity.

An angled housing part for an electrical connector includes a first section having a first flange surface, a second section having a second flange surface, and a bellows section arranged between the first section and the second section. The first flange surface is angled with respect to the second section. The first section and the second section are movable relative to one another upon elastic deformation of the bellows section.

A field installable connector that conforms to standard physical requirements while providing high performance at high speeds. The connector includes a housing holding conductive elements configured for pressure mount to a printed circuit board. The housing has a mating surface, a mounting surface opposite the mating surface in a vertical direction, and a slot extending through the mating surface. Each conductive element has a mating end curving into the slot, and a mounting end extending out of the mounting surface at an angle to the vertical direction. The mounting end has a contact surface configured to make contact with a contact pad on the board. The housing includes holes aligned with holes of the board such that a connecting member can extend through the aligned holes to secure the housing to the board and provide force for sufficient contact between conductive elements and respective contact pads.

A field installable connector that conforms to standard physical requirements while providing high performance at high speeds. The connector includes a housing holding conductive elements configured for pressure mount to a printed circuit board. The housing has a mating surface, a mounting surface opposite the mating surface in a vertical direction, and a slot extending through the mating surface. Each conductive element has a mating end curving into the slot, and a mounting end extending out of the mounting surface at an angle to the vertical direction. The mounting end has a contact surface configured to make contact with a contact pad on the board. The housing includes holes aligned with holes of the board such that a connecting member can extend through the aligned holes to secure the housing to the board and provide force for sufficient contact between conductive elements and respective contact pads.