A connection method of an RF cable end connector and a coaxial cable and an internal terminal used thereof are provided. An insulator is formed outside a body of the internal terminal by embedded molding, making the internal terminal have a composite structure integrated with the insulator. The internal terminal can be connected to the coaxial cable by, for example, clamping. This allows connection between the RF cable end connector and the coaxial cable to be easily accomplished by automatic processes, thereby reducing fabrication costs of RF cable end connector jumpers.

A plug connector arrangement having a plug connector and a cable connected thereto, at least one inner conductor and an outer conductor surrounding the inner conductor, wherein the outer conductor of the cable is electrically connected to an outer conductor housing of the plug connector. The plug connector arrangement additionally has a sleeve part which surrounds the inner conductor, has approximately the same inner diameter (D) as the outer conductor (34) of the cable, adjoins a front axial end (A) of the outer conductor, and continues a shielding of the inner conductor in the direction of the front cable end.

A plug connector arrangement having a plug connector and a cable connected thereto, at least one inner conductor and an outer conductor surrounding the inner conductor, wherein the outer conductor of the cable is electrically connected to an outer conductor housing of the plug connector. The plug connector arrangement additionally has a sleeve part which surrounds the inner conductor, has approximately the same inner diameter (D) as the outer conductor (34) of the cable, adjoins a front axial end (A) of the outer conductor, and continues a shielding of the inner conductor in the direction of the front cable end.

There is provided a coaxial connector that can suitably bias a movable insulator to the side of a socket and maintain matched impedance. The coaxial connector includes a movable insulator that is fitted in a central conductor so as to be slidable and is housed in an insulator housing so as to be movable in an axial direction; and a biasing rubber member that is interposed between a partition disposed in the recesses of the insulator housing and the movable insulator. When the biasing rubber member connects the socket to the plug, the movable insulator is pushed in by a pushing force from a socket, and elastic pillars are bent in an arc shape.

An edge launch radio frequency (RF) signal connector includes ground contact tabs that have radially extending arms. The arms cover a gap between a substrate, such as a circuit board, and the connector to reduce the RF ground path between the RF reference ground and a signal pin supported by the connector. The arms extend radially inwardly from the protruding ground contact tabs toward a central support aperture that supports the signal pin. The arms and the ground contact tabs are formed integrally with the main connector body as one piece. The arms and the ground contact tabs may be planar in shape such that the arms and the ground contact tabs lie flush on the substrate when the connector is arranged over the edge of the substrate.

A controlled impedance compressible electrical connector having a housing with at least one terminal receiving cavity which extends from a first surface of the housing to a second surface of the housing. A terminal assembly is positioned in each of the at least one terminal receiving cavities of the housing. The terminal assembly has a first fixed center terminal, a second movable center terminal, a fixed outer shell, a movable outer shell, and a resilient member. The terminal assembly is configured to allow impedance of the electrical connector to be maintained as the second movable center terminal and the movable outer shell are moved relative to the first fixed center terminal, the fixed outer shell and the housing.

A controlled impedance compressible electrical connector having a housing with at least one terminal receiving cavity which extends from a first surface of the housing to a second surface of the housing. A terminal assembly is positioned in each of the at least one terminal receiving cavities of the housing. The terminal assembly has a first fixed center terminal, a second movable center terminal, a fixed outer shell, a movable outer shell, and a resilient member. The terminal assembly is configured to allow impedance of the electrical connector to be maintained as the second movable center terminal and the movable outer shell are moved relative to the first fixed center terminal, the fixed outer shell and the housing.

An electrical plug-in connector for differential signal transmission, having an external conductor contact element, a dielectric and at least one internal conductor contact element pair for differential signal transmission. The dielectric extends along a longitudinal axis through the external conductor contact element. The internal conductor contact element pair has a first internal conductor contact element and a second internal conductor contact element which extend along the longitudinal axis through the dielectric. The external conductor contact element and/or the dielectric have a compensation geometry in order to compensate for an asymmetry of the internal conductor contact element pair with respect to the longitudinal axis. As an alternative or in addition, it is provided that the internal conductor contact element pair has a compensation geometry in order to compensate for an asymmetry of the external conductor contact element and/or of the dielectric with respect to the longitudinal axis.

A differential mode instrumentation cable for improving the signal integrity of audio signals in different environments including use of microphones, speaker cable, audiophile cables and analog audio balanced/differential tie lines comprising a first triaxial cable and a second triaxial cable placed side-by-side and mounted together, said first coaxial cable and said second coaxial cable including a wired connection that includes an active driven shield buffer circuit in each triaxial cable having an inner conductor for voltage in from the positive polarity and minus polarity and the voltage out driven guard shield with series breakout resistor connected to the each triaxial inner shield.

Technology of the present invention suppresses a decrease in the impedance of an inner conductor. A connector 10 includes an inner conductor 21, an outer conductor 41 that surrounds the inner conductor 21, and a dielectric 61 arranged between the inner conductor 21 and the outer conductor 41. The dielectric 61 includes a cavity 63 that extends in a predetermined direction and a locking hole 64 formed in an inner peripheral face of the cavity 63. The inner conductor 21 includes an inner conductor body 23 arranged in the cavity 63, and a locking portion 24 that bulges from the inner conductor body 23 and can enter and be locked to the locking hole 64. The locking portion 24 extends along the predetermined direction and is shaped as a double-supported beam whose upper and lower end portions are supported by the inner conductor body 23.