There is provided an interface module, including an interface for connection with a signal connector, a cage for guiding the signal connector towards the interface and a heat sink. The cage has a cage portion that is configured to move from a first position to a second position upon insertion of the signal connector into the cage. In the first position, the cage portion is not in thermal contact with the heat sink. When in the second position, the cage portion is in thermal contact with the heat sink.

There is provided an interface module, including an interface for connection with a signal connector, a cage for guiding the signal connector towards the interface and a heat sink. The cage has a cage portion that is configured to move from a first position to a second position upon insertion of the signal connector into the cage. In the first position, the cage portion is not in thermal contact with the heat sink. When in the second position, the cage portion is in thermal contact with the heat sink.

A connector comprises a cage having a plurality of insertion chambers arranged in parallel, a plurality of radiators each mounted on a top wall of one of the plurality of insertion chambers, and a plurality of elastic clips each adapted to fix one of the radiators on the top wall of one of the insertion chambers. Each clip has a pair of longitudinal beams and a pair of elastic lateral beams connected between the pair of longitudinal beams. The pair of elastic lateral beams cross the radiator in a lateral direction of the cage and press the radiator on the top wall of the insertion chamber. The pair of longitudinal beams are located at a pair of sides of the radiator opposite to each other in the lateral direction and are locked to the top wall of the insertion chamber.

A connector comprises a cage having a plurality of insertion chambers arranged in parallel, a plurality of radiators each mounted on a top wall of one of the plurality of insertion chambers, and a plurality of elastic clips each adapted to fix one of the radiators on the top wall of one of the insertion chambers. Each clip has a pair of longitudinal beams and a pair of elastic lateral beams connected between the pair of longitudinal beams. The pair of elastic lateral beams cross the radiator in a lateral direction of the cage and press the radiator on the top wall of the insertion chamber. The pair of longitudinal beams are located at a pair of sides of the radiator opposite to each other in the lateral direction and are locked to the top wall of the insertion chamber.

The connector structure selectively uses either a UTP connector or an STP connector. The UTP connector includes UTP connection terminals connected to respective electric wires of a UTP cable and a UTP dielectric having a pair of housing portions in which the UTP connection terminals are housed. The STB connector includes STP connection terminals connected to respective electric wires of an STP cable and an STP dielectric having a pair of housing portions in which the STP connection terminals are housed. In the UTP dielectric, at least a partition wall for partitioning the pair of housing portions is made of a material having a relatively high dielectric constant. In the STP dielectric, at least a partition wall for partitioning the pair of housing portions is made of a material having a relatively low dielectric constant.

The connector structure selectively uses either a UTP connector or an STP connector. The UTP connector includes UTP connection terminals connected to respective electric wires of a UTP cable and a UTP dielectric having a pair of housing portions in which the UTP connection terminals are housed. The STB connector includes STP connection terminals connected to respective electric wires of an STP cable and an STP dielectric having a pair of housing portions in which the STP connection terminals are housed. In the UTP dielectric, at least a partition wall for partitioning the pair of housing portions is made of a material having a relatively high dielectric constant. In the STP dielectric, at least a partition wall for partitioning the pair of housing portions is made of a material having a relatively low dielectric constant.

In one embodiment, a method includes identifying optical transceivers installed in optical module ports at a network device based on input received at electrical interfaces at the network device, identifying at least one optical module port without an optical transceiver installed, determining if a plug is inserted into the optical module port, wherein an electrical signal indicates insertion of the plug into the optical module port, and raising an alarm if the optical module port is open. Insertion of the plug into the optical module port reduces airflow bypass, electromagnetic interference leakage, and contamination without the optical transceiver installed in the optical module port. The plug is also disclosed herein.

A first inner housing and a second inner housing are combined to form a combined inner housing, in which the first inner housing having a plurality of mutually independent insertion holes is formed of a first dielectric or an electric conductor, and the second inner housing having a plurality of mutually independent terminal-housing chambers is formed of a second dielectric. Terminals of a twisted-pair cable are inserted and housed one-to-one in the terminal-housing chambers of the combined inner housing. The twist-released sections of sheathed cables of the twisted-pair cable are inserted and housed one-to-one in the insertion holes of the combined inner housing. The combined inner housing is covered with a shield member, and the combined inner housing and the shield member are housed in an outer housing.

A first inner housing and a second inner housing are combined to form a combined inner housing, in which the first inner housing having a plurality of mutually independent insertion holes is formed of a first dielectric or an electric conductor, and the second inner housing having a plurality of mutually independent terminal-housing chambers is formed of a second dielectric. Terminals of a twisted-pair cable are inserted and housed one-to-one in the terminal-housing chambers of the combined inner housing. The twist-released sections of sheathed cables of the twisted-pair cable are inserted and housed one-to-one in the insertion holes of the combined inner housing. The combined inner housing is covered with a shield member, and the combined inner housing and the shield member are housed in an outer housing.

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.