The application relates to a connector, intended to transmit radio frequency RF signals, of longitudinal axis X, including: a central contact under the form of an elongated flat strip which at least one of its ends is shaped as a fork with two flexible branches to define inwardly a cavity extending along the axis X for receiving a contact pin of one complementary connector, the two flexible branches of the fork being configured such that to apply a contact force to the contact pin; at least one solid insulating structure in which the central contact is mechanically retained, one of its ends of the insulating structure being configured to let the two flexible branches to move freely radially and to guide the contact pin while enabling its swivelling when inserted into the cavity (C) defined by the fork.

Provided are a conductive sheet structure and a high-speed connector. The conductive sheet includes a conductive sheet, and a plurality of elastic arms are disposed on the conductive sheet with spacings. Each elastic arm includes a connecting section, a tilt section and a contact section which are connected in sequence. The connecting section is fixedly connected to the conductive sheet. The tilt section is tilted relative to the conductive sheet and the tilt angle between the tilt section and the conductive sheet is variable. The contact section is used for contacting with a grounding terminal on a high-speed connector.

Provided are a conductive sheet structure and a high-speed connector. The conductive sheet includes a conductive sheet, and a plurality of elastic arms are disposed on the conductive sheet with spacings. Each elastic arm includes a connecting section, a tilt section and a contact section which are connected in sequence. The connecting section is fixedly connected to the conductive sheet. The tilt section is tilted relative to the conductive sheet and the tilt angle between the tilt section and the conductive sheet is variable. The contact section is used for contacting with a grounding terminal on a high-speed connector.

A card edge connector includes a longitudinal insulating housing including two long walls and a bottom wall connecting with the long wall and defining a card slot in a longitudinal direction among the long walls and the bottom wall, two rows of contact arranged in the long walls respectively. Each contact includes a retaining portion, a spring portion extending from the retaining portion and leg portion extending from the retaining portion and out of the insulating housing. The spring portions define contacting portions projecting into the card slot. Each contact is formed by directly punching out from a metal plate, the retaining portions define an outer edge and inner edge interfered with the insulating housing and two opposite plane faces connecting with the outer and inner edge and disposed perpendicular to the longitudinal direction.

A card edge connector includes a longitudinal insulating housing including two long walls and a bottom wall connecting with the long wall and defining a card slot in a longitudinal direction among the long walls and the bottom wall, two rows of contact arranged in the long walls respectively. Each contact includes a retaining portion, a spring portion extending from the retaining portion and leg portion extending from the retaining portion and out of the insulating housing. The spring portions define contacting portions projecting into the card slot. Each contact is formed by directly punching out from a metal plate, the retaining portions define an outer edge and inner edge interfered with the insulating housing and two opposite plane faces connecting with the outer and inner edge and disposed perpendicular to the longitudinal direction.

A radio-frequency connector assembly includes a radio-frequency line, connector male terminals, connector female terminals, and a circuit board, wherein each connector male terminal includes a male terminal substrate; each connector female terminal includes a female terminal substrate; the connector male terminal further includes a shielding case which shields the male terminal substrate and is conductive with the radio-frequency line in a grounding manner; and the connector female terminal further includes a shielding frame which is internally provided with the female terminal substrate and is circumferentially seamless entirely, and the bottom end of the shielding frame makes contact with the circuit board to form an annular contact region, so that signals of the connector female terminals will not leak sideways; and the shielding cases can prevent signal leakage and signal interference from the top of the shielding frame, so that matched signal terminals are kept in a fully-shielded operating environment.

An electrical connector assembly includes a contact module having an upper part and a lower part stacked with each other. The upper part includes a front/outer upper unit and a rear/inner upper unit and the lower part includes a front/outer lower unit and a rear/inner lower unit. Each unit includes an insulative body and a plurality of contacts integrally formed with the insulative body via an insert-molding process. The insulative body includes a middle sector and a pair of side sectors. The contacts include side-band contacts retained in the middle sector and differential-pair contacts retained in the side sectors.

An electrical connector includes an insulative elongated housing, and a plurality of contacts retained to the housing. The housing includes a base extending along the longitudinal direction and a mating tongue extending forwardly from the base in a front-to-back direction perpendicular to the longitudinal direction. Each contact includes a contacting/mating section exposed upon the mating tongue. The contacts include a plurality of differential-pair signal contacts and a plurality of grounding contacts alternately arranged with each other along the longitudinal direction. Each differential-pair signal contact is associated with a metallic wiping piece in front with a tiny gap so as to have the distance between the rear end of the contacting section and the front edge of the wiping piece is still equal to 3.9 mm which is regulated by the industry standard specification as a full length of the contacting section of the traditional contact.

The present disclosure provides a high-frequency magnetoimpedance testing apparatus and method. A testing platform in the apparatus is arranged within a Helmholtz coil and connected to a modulating electric current source and a high-frequency impedance analyzer, respectively; the Helmholtz coil is connected to a DC power source; a processor is connected to the high-frequency impedance analyzer and the DC power source separately; the testing platform includes a first double-sided copper-clad plate, and mode transition switches and connection terminals that are arranged on the first double-sided copper-clad plate; one end of the first double-sided copper-clad plate is connected to the high-frequency impedance analyzer, while the other end of the same is connected to a load; the mode transition switches are connected to the modulating electric current source. The present disclosure can realize in-situ current modulation of metallic fibers and high-frequency magnetoimpedance testing, and improve the testing accuracy.

The present disclosure provides a high-frequency magnetoimpedance testing apparatus and method. A testing platform in the apparatus is arranged within a Helmholtz coil and connected to a modulating electric current source and a high-frequency impedance analyzer, respectively; the Helmholtz coil is connected to a DC power source; a processor is connected to the high-frequency impedance analyzer and the DC power source separately; the testing platform includes a first double-sided copper-clad plate, and mode transition switches and connection terminals that are arranged on the first double-sided copper-clad plate; one end of the first double-sided copper-clad plate is connected to the high-frequency impedance analyzer, while the other end of the same is connected to a load; the mode transition switches are connected to the modulating electric current source. The present disclosure can realize in-situ current modulation of metallic fibers and high-frequency magnetoimpedance testing, and improve the testing accuracy.