A connector includes a housing having a bore therein. A center conductor element is positioned in the bore and includes a center conductor pin. The center conductor pin is spring-biased to move longitudinally in the housing bore for being compressed. A ground sleeve element is coaxially arranged around the center conductor element and is also spring-biased to move longitudinally in the housing bore for being compressed. The center conductor element and ground sleeve element are coupled together for moving together in the housing bore when compressed. The compressed elements maintain their same coaxial position in the housing bore with respect to each other when the connector is compressed.

Provided are a shielded terminal and a shielded connector that can prevent a short circuit between a connection portion for an electric component and an outer conductor. A shielded terminal includes an outer conductor, a connection portion for an electric component, and an insulator, wherein the outer conductor has a crimping portion that is crimped onto an end portion of a shielded wire, a bottom surface portion in which an opening is formed forward of the crimping portion, and side surface portions provided on both the left and right sides of the bottom surface portion, the connection portion is disposed between the left and right side surface portions and formed by connecting a center conductor of the shielded wire and the electric component to each other, and the insulator has left and right side walls that are located between the connection portion and the respective side surface portions.

It is aimed to improve transmission characteristics. A connector device is provided with a first terminal including a first inner conductor and to be mounted on a first circuit board, and an elongated movable terminal including a movable-side inner conductor and to be arranged between the first terminal and a second terminal. The first inner conductor includes a mounting portion to be connected to the first circuit board and a first connecting portion extending from the mounting portion toward the movable terminal. The movable-side inner conductor includes a movable-side connecting portion to be connected to the first connecting portion while being fit to the first connecting portion in a length direction of the movable terminal and a shaft-like body portion extending from the movable-side connecting portion toward the mating terminal. An outer diameter of the body portion and an outer diameter of the mounting portion are set equal.

It is aimed to improve transmission characteristics. A connector device is provided with a first terminal including a first inner conductor and to be mounted on a first circuit board, and an elongated movable terminal including a movable-side inner conductor and to be arranged between the first terminal and a second terminal. The first inner conductor includes a mounting portion to be connected to the first circuit board and a first connecting portion extending from the mounting portion toward the movable terminal. The movable-side inner conductor includes a movable-side connecting portion to be connected to the first connecting portion while being fit to the first connecting portion in a length direction of the movable terminal and a shaft-like body portion extending from the movable-side connecting portion toward the mating terminal. An outer diameter of the body portion and an outer diameter of the mounting portion are set equal.

A coaxial terminator for terminating a coaxial equipment port includes a female connector, an outer housing, at least one support element, a center conductor, cured resin dielectric, and one or more resistive elements. The female connector is disposed within the outer housing, is supported within the outer housing by the at least one support element, and is configured to receive a male pin of the coaxial equipment port. The center conductor has a proximal portion and a distal portion and is coaxially coupled to the female connector at the proximal portion and encircled by cured resin dielectric at the distal portion. The cured resin dielectric is cured in place between the center conductor and the outer housing. The one or more resistive elements are in electrical communication at a first end with the center conductor and at a second end with the inner housing.

Disclosed is a cable adaptor comprising a first member which is conductive and comes into contact with a signal pin of the cable, a second member disposed outside the first member and coupled to the first member, a third member which is conductive and disposed outside the second member, and a contact pin fixed to the first member. Here, the first member includes a first body coupled to the second member and a first contact portion which extends from the first body and comes into contact with the signal pin. The third member includes a second body coupled to the second member and a second contact portion which extends from the second body and comes into contact with the outer conductor. A plurality of first contact points of the signal pin and the first contact portion are arranged at same intervals along a circumferential direction of the signal pin.

Disclosed is a cable adaptor which is connected to a cable including an outer conductor. The adaptor includes a contact pin which comes into contact with a signal pin of the cable, a first member which is conductive and disposed inside and coupled to the contact pin, a second member disposed outside and coupled to the contact pin, and a third member which is conductive and disposed outside the second member. Here, the contact pin includes a first body coupled to the second member, a first contact portion which is conductive and extends from one side of the first body to come into contact with the signal pin, and a second contact portion which extends from the other side of the first body and comes into contact with an object being tested. The third member includes a second body coupled to the second member and a third contact portion.

A method for crimping an electrical cable with a shielding braid and an insulation enclosing the shielding braid includes removing the insulation at a predetermined area to expose an exposed portion of the shielding braid. The method includes crimping an inner crimp sleeve onto the insulation adjacent to the predetermined area and then bending back the exposed portion of the shielding braid at least sectionally over the inner crimp sleeve.

A connector and shielding ring for use with the connector includes a male portion with a shroud and a center conductor and a female portion with a jack and a socket positioned to receive the center conductor. A conductive shielding ring is positioned between the mated connector portions. The shielding ring has a body configured for surrounding flexible tines of the female portion jack and is configured to be captured between the tines and the shroud for providing a grounding path between the male and female portions of the connector. The shielding ring body has an inner surface with a diameter and an outer surface with a diameter and has a taper portion formed on a distal end of the shielding ring body for engaging a surface of the shroud. The shielding ring body has a lip extending radially inwardly at the proximal end for engaging the tines of the female portion when the male and female portions of the connector are mated.

A hardline connector for providing high frequency performance includes a body portion configured to be coupled with an interface port. The body portion is configured to house a collet and an insulator, the collet includes a pin portion and a gripping portion that is configured to receive a center conductor of a hardline coaxial cable, and the gripping portion is configured to define a forward facing surface at a forward end of the gripping portion of the collet. The body portion is configured to minimize peaks and valleys of impedance levels within the connector relative to a desired 75 ohm impedance such that the hardline connector is configured to improve return loss performance over a wider frequency bandwidth without degrading electrical, mechanical, and environmental performance of the connector by minimizing peaks and valleys of impedance levels within the connector relative to a desired 75 ohm impedance. The hardline connector is configured to achieve a return loss of −20 dB or better over a frequency range of 5 MHz to 3 GHz.