A backplane connector assembly includes a first backplane connector and a second backplane connector. The first backplane connector includes a number of first conductive terminals, a first insulating frame, a first metal shield and a second metal shield. The first metal shield includes a first elastic piece, and the second metal shield includes a second elastic piece. The second backplane connector includes a number of second differential signal terminals, an insulating block sleeved on the second differential signal terminals, and a metal shell sleeved on the insulating block. When the first backplane connector is mated with the second backplane connector, the first elastic piece and the second elastic piece are in contact with the metal shell to increase the grounding shielding area, reduce crosstalk and improve the quality of signal transmission.

A backplane connector includes a wafer. The wafer includes a number of conductive terminals, an insulating frame, a first metal shield and a second metal shield located on opposite sides of the insulating frame. The insulating frame includes a number of first posts and a number of second posts. The first metal shield has a number of first mounting holes to receive the first posts. The second metal shield has a number of second mounting holes to receive the second posts. With this arrangement, the first metal shield and the second metal shield can be easily positioned with the insulating frame.

A backplane connector includes a number of conductive terminals, an insulating frame, a first metal shield and a second metal shield. Each conductive terminal includes a connection portion. The conductive terminals include differential signal terminals, a first ground terminal and a second ground terminal. The first metal shield and the second metal shield are respectively in contact with two opposite side surfaces of the first ground terminal and the second ground terminal. As a result, a shielding cavity surrounding the connection portions of the differential signal terminals is formed. This arrangement can provide better shielding for the differential signal terminals over the length of the connection portion, reduce crosstalk, and improve the quality of signal transmission.

A radio-frequency coaxial connector, comprising a radio-frequency plug and a radio-frequency socket. The radio-frequency plug comprises a tubular plug outer conductor, a plurality of first conductor plates are axially arranged inside the plug outer conductor along the plug outer conductor, and a second conductor plate is fixedly provided at the central axis of the plug outer conductor. The radio-frequency socket comprises a tubular socket shell, a front end of the socket shell is provided with a first slot matching a first conductor plate, a tuning fork-shaped socket inner conductor is provided at the central axis of the socket shell, the head end of the socket inner conductor is provided with a second slot matching the second conductor plate, and an insulation sleeve is filled between the tail part of the socket inner conductor and the inner wall of the socket shell.

A high-speed communication connector capable of improving transmission quality and of controlling transmission characteristics is disclosed. The connector is a board-to-board-type connector for high-speed data communication in band of 10 to 25 GHz, and is constructed so as to reduce signal interference by virtue of a finger body having a PCB structure and shield structures between signal lines of a receptacle body filled with a dielectric material and to realize matching between impedances by virtue of the dielectric material and the signal lines.

A connector (10) according to the present disclosure includes an insulator to be fitted to a connection object (60), and contacts (50) attached to the insulator. Each of the contacts (50) includes a contact portion (59), a first elastic portion (54A), a first adjustment portion (54B1), and a second adjustment portion (54B2). The contact portion (59) electrically contacts the connection object (60) when the insulator and the connection object (60) are fitted together. The first elastic portion (54A) is elastically deformable and extends from a first base (51) supported by the insulator. The first adjustment portion (54B1) is formed continuously with the first elastic portion (54A) and has an electric conductivity higher than that of the first elastic portion (54A). The second adjustment portion (54B2) is formed continuously with the first adjustment portion (54B1) and has an electric conductivity lower than that of the first adjustment portion (54B1).

A connector (10) according to the present disclosure includes an insulator to be fitted to a connection object (60), and contacts (50) attached to the insulator. Each of the contacts (50) includes a contact portion (59), a first elastic portion (54A), a first adjustment portion (54B1), and a second adjustment portion (54B2). The contact portion (59) electrically contacts the connection object (60) when the insulator and the connection object (60) are fitted together. The first elastic portion (54A) is elastically deformable and extends from a first base (51) supported by the insulator. The first adjustment portion (54B1) is formed continuously with the first elastic portion (54A) and has an electric conductivity higher than that of the first elastic portion (54A). The second adjustment portion (54B2) is formed continuously with the first adjustment portion (54B1) and has an electric conductivity lower than that of the first adjustment portion (54B1).

An interconnection system with a compliant shield between a connector and a substrate such as a PCB. The compliant shield may provide current flow paths between shields internal to the connector and ground structures of the PCB. The connector, compliant shield and PCB may be configured to provide current flow in locations relative to signal conductors that provide desirable signal integrity for signals carried by the signal conductors. In some embodiments, the current flow paths may be adjacent the signal conductors, offset in a transverse direction from an axis of a pair of conductors. Such paths may be created by tabs extending from connector shields. A compliant conductive member of the compliant shield may contact the tabs and a conductive pad on a surface of the PCB. Shadow vias, running from the surface pad to internal ground structures may be positioned adjacent the tip of the tabs.

A connector (10) according to the present disclosure is the connector (10) to be fitted to a connection object (60) and includes a first insulator (20), a second insulator (30) movable relative to the first insulator (20), and a plurality of arranged contacts (50) attached to the first insulator (20) and the second insulator (30). Each of the contacts (50) includes a wide portion located on at least one of a first insulator side and a second insulator side. The wide portion protrudes from another portion of each of the contacts (50) that extends along one of the insulators where the wide portion is located toward the other insulator in a direction substantially orthogonal to an arrangement direction of the contacts (50).

A connector (10) according to the present disclosure is the connector (10) to be fitted to a connection object (60) and includes a first insulator (20), a second insulator (30) movable relative to the first insulator (20), and a plurality of arranged contacts (50) attached to the first insulator (20) and the second insulator (30). Each of the contacts (50) includes a wide portion located on at least one of a first insulator side and a second insulator side. The wide portion protrudes from another portion of each of the contacts (50) that extends along one of the insulators where the wide portion is located toward the other insulator in a direction substantially orthogonal to an arrangement direction of the contacts (50).