A receptacle connector assembly includes a receptacle cage having walls defining a cavity and a divider in the cavity including upper and lower panels separated by a gap and separating the cavity into upper and lower module channels receiving corresponding pluggable modules. The receptacle connector assembly includes a communication connector in the cavity having a housing holding upper and lower contact modules. The receptacle connector assembly includes a light pipe assembly including a first light pipe member coupled to the communication connector and a second light pipe member coupled to the divider. The second light pipe member receives light from the first light pipe member at a separable mating interface.

A shield connector includes a male shield terminal (20) mounted in a male housing (10), male inner conductors (37) constituting the male shield terminal (20) and to be connected to female inner conductors (78) by connecting both housings (10, 70), a male outer conductor (21) surrounding the male inner conductors (37) via a male dielectric (31) and configured to contact a female outer conductor (76) by connecting the both housings (10, 70), a tube (25) formed in the male outer conductor (21) and surrounding the female outer conductor (76) with the housings (10, 70) connected, and resilient contact pieces (26) formed in the male outer conductor (21) and to be resiliently connected to an outer periphery of the female outer conductor (76). The tube (25) is continuous over an entire periphery, thereby restricting an expanding deformation thereof.

A shield terminal (T) includes inner conductors (52) connected to cores (62) of a shielded cable (60) and a dielectric (46) accommodates the inner conductors (52). A body (11) of an outer conductor (10) includes a tubular holding portion (14) that surrounds the dielectric (46) and a crimping portion (32) connected to a front of a shield layer (65) of the shielded cable (60). An upper member (35) of the outer conductor (10) is separate from the body (11) and with the body (11) surrounds the cores (62) over an entire periphery. A second hook (39) on a front part of the upper member (35) is lockable to a rear edge of the holding portion (14). A second guide means (29) guides the upper member (35) to a proper position while allowing the upper member (35) to swing with the second hook (39) as a fulcrum.

A method of forming a cable connection system. A base and a rack are provided, and the base is coupled with the rack, using a coupling mechanism, during a connect mode of operation. The rack includes a first rack surface and a second rack surface perpendicular to the first rack surface, wherein the first rack surface is perpendicular to a raised floor surface, wherein the second rack surface is on, and parallel to, the raised floor surface. The base is coupled to cables connected to the rack, wherein the base includes a first base surface, a second base surface perpendicular to the first base surface, and an array of slots into which corresponding network servers are screwed into place. The coupling mechanism includes a group of base connectors on the first surface of the base and a group of rack connectors on the first surface of the rack.

A method of forming a cable connection system. A base and a rack are provided, and the base is coupled with the rack, using a coupling mechanism, during a connect mode of operation. The rack includes a first rack surface and a second rack surface perpendicular to the first rack surface, wherein the first rack surface is perpendicular to a raised floor surface, wherein the second rack surface is on, and parallel to, the raised floor surface. The base is coupled to cables connected to the rack, wherein the base includes a first base surface, a second base surface perpendicular to the first base surface, and an array of slots into which corresponding network servers are screwed into place. The coupling mechanism includes a group of base connectors on the first surface of the base and a group of rack connectors on the first surface of the rack.

A communication system includes a host circuit board and an interposer assembly coupled to the host circuit board having an interposer substrate including an upper surface and a lower surface. The interposer assembly has host circuit board contacts electrically connected to contact pads of the host circuit board and cable assembly contacts coupled to a pluggable module. The pluggable module includes a mating interface along a bottom of the pluggable module facing the interposer assembly. The pluggable module includes a cable assembly having a cable at the cable end. The cable has a signal conductor and a ground conductor being electrically connected to corresponding cable assembly contacts of the interposer assembly at the upper surface of the interposer substrate.

A communication system includes a host circuit board and an interposer assembly coupled to the host circuit board having an interposer substrate including an upper surface and a lower surface. The interposer assembly has host circuit board contacts electrically connected to contact pads of the host circuit board and cable assembly contacts coupled to a pluggable module. The pluggable module includes a mating interface along a bottom of the pluggable module facing the interposer assembly. The pluggable module includes a cable assembly having a cable at the cable end. The cable has a signal conductor and a ground conductor being electrically connected to corresponding cable assembly contacts of the interposer assembly at the upper surface of the interposer substrate.

The present invention relates to methods and systems for minimizing alien crosstalk between connectors. Specifically, the methods and systems relate to isolation and compensation techniques for minimizing alien crosstalk between connectors for use with high-speed data cabling. A frame can be configured to receive a number of connectors. Shield structures may be positioned to isolate at least a subset of the connectors from one another. The connectors can be positioned to move at least a subset of the connectors away from alignment with a common plane. A signal compensator may be configured to adjust a data signal to compensate for alien crosstalk. The connectors are configured to efficiently and accurately propagate high-speed data signals by, among other functions, minimizing alien crosstalk.

An electrical receptacle connector is mounted within a metallic cage for mating with a QSFP module received within the cage. The contacts of the cable receptacle connector are arranged with two groups, of which one are connected to the printed circuit board on which the cage is mounted, and the other are connected to the wires which are further connected to a board-mount receptacle connector mounted on another printed circuit board on which the CPU (Central Processing Unit) socket is mounted. Each board-mount receptacle connector corresponds to more than one cable receptacle connector.

An electrical receptacle connector is mounted within a metallic cage for mating with a QSFP module received within the cage. The contacts of the cable receptacle connector are arranged with two groups, of which one are connected to the printed circuit board on which the cage is mounted, and the other are connected to the wires which are further connected to a board-mount receptacle connector mounted on another printed circuit board on which the CPU (Central Processing Unit) socket is mounted. Each board-mount receptacle connector corresponds to more than one cable receptacle connector.