A shield terminal is provided with a pair of female inner conductors including box-shaped connecting portions into which tabs of male inner conductors are inserted, a female dielectric configured by uniting a first member and a second member made of a material having a lower dielectric constant than the first member, the pair of female inner conductors being accommodated in the female dielectric while being arranged in parallel, and a front separation wall portion formed in the second member and disposed to partition between a pair of the box-shaped connecting portions. Since the female dielectric is divided into the first member and the second member and the front separation wall portion is formed in the second member having a lower dielectric constant, a material cost can be reduced as compared to the case where the both members are made of a material having a low dielectric constant.

A shield terminal is provided with a pair of female inner conductors including box-shaped connecting portions into which tabs of male inner conductors are inserted, a female dielectric configured by uniting a first member and a second member made of a material having a lower dielectric constant than the first member, the pair of female inner conductors being accommodated in the female dielectric while being arranged in parallel, and a front separation wall portion formed in the second member and disposed to partition between a pair of the box-shaped connecting portions. Since the female dielectric is divided into the first member and the second member and the front separation wall portion is formed in the second member having a lower dielectric constant, a material cost can be reduced as compared to the case where the both members are made of a material having a low dielectric constant.

A connector structure includes an insulated housing, at least one terminal assembly and at least one conductive assembly. The terminal assembly is disposed in the insulated housing. The conductive assembly is disposed at one side of the terminal assembly by crossing over the terminal assembly. The conductive assembly includes at least one metal piece and at least one polymer included conductive component. The polymer included conductive component is used to electrically connect the at least one metal pieces. The metal piece includes at least one spring finger contact, and the spring finger contact is electrically connected to the ground terminal in the terminal assembly. In additional, a terminal assembly structures of connector is also provided.

To provide a connector module with stable EMC, a connector module includes: a receptacle on a substrate; and a plug electrically connected to the receptacle and electrically connectable to a communication cable, the plug including: a connector including an outer conductor electrically connectable to the communication cable; and a connection member connecting the connector to the receptacle and electrically connected to a ground line on the substrate, the outer conductor including: a cylindrical conductor body; and an annular flange extending from the conductor body to a radially outward side, the flange including a step on a facing side facing the connection member, the connection member being in contact with an upper level portion or a lower level portion. [Selected Figure] FIG. 12

An electrical connector includes an insulating body and a terminal module. The terminal module includes a first terminal module, a second terminal module, and a shielding piece. The first terminal module includes a number of first conductive terminals. Each first conductive terminal includes a first elastic contact arm and a first tail portion. The second terminal module includes a number of second conductive terminals. Each second conductive terminal includes a second elastic contact arm and a second tail portion. The shielding piece includes a connecting portion and a number of ground terminals. The ground terminals include a number of first ground elastic arms arranged in a same row as the first elastic contact arms and a number of second ground elastic arms arranged in a same row as the second elastic contact arms. As a result, the shielding performance of the electrical connector is improved.

An assembly for terminating a high speed cable with an EMI braided shield, The assembly a shell housing, a crosstalk shield and a constant force spring. The shell housing has a mating end and a conductor receiving end. A recessed portion is provided proximate the conductor receiving end, the recessed portion has an outer diameter. The crosstalk shield is provided in the shell housing. The constant force spring is positioned in the recessed portion of the shell housing. The constant force spring has an opening with an inner diameter which is less than the outer diameter of the recessed portion. The constant force spring is circumferentially wrapped about the EMI braided shield to mechanically and electrically secure the EMI braided shield to the recessed portion of the shell housing.

The present disclosure provides an electrical connector including an insulating housing, a number of terminals and a lossy member. The terminals include a number of ground terminals and a number of signal terminals. The ground terminals and the signal terminals are set adjacently to each other but do not contact each other. The ground terminals do not directly contact the lossy member. As a result, installation consistency of the ground terminals can be achieved, thereby improving the electrical performance of the electrical connector.

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.

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.

High density pluggable electrical connector having a number of electrical contacts exceeding sixty and a contact density on a plugging interface of the connector of at least forty contacts per square centimeter, comprising a casing and a terminal unit mounted within the casing, the terminal unit comprising a housing with a module receiving cavity formed within the housing, and a plurality of terminal modules insertably received in the module receiving cavity in a stacked arrangement. Each terminal module comprises a plurality of contacts mounted in a dielectric terminal module housing, the terminal modules having a width W to height H ratio W/H greater than three.