Abstract: A communications system includes a plurality of patch panels, wherein each patch panel has a plurality of connector ports on a front surface thereof that are each connected to a respective communication line, and one or more optical couplers/connector ports on a rear surface thereof for linking two or more patch panels together. A cable for linking patch panels includes opposite ends and a respective connector at each end that is configured to be removably secured within a respective coupler/connector port on the rear surface. Each connector has an RFID tag attached thereto. An RF antenna is secured to each patch panel adjacent each respective coupler, and each antenna is configured to activate and read information from a cable RFID tag when a cable connector is secured within a coupler adjacent thereto.

Abstract: A datacommunication interconnection system includes (a) an extension trunk cable-connector assembly and (b) a trunk cable-connector assembly. The extension trunk cable-connector assembly comprises: a first cable including a plurality of first subunits, each of the first subunits comprising a plurality of twisted pairs of conductors; a jack attached to one end of the cable; and a plug attached to an opposite end of the cable. Each of the jack and the plug includes a contact for each of the conductors of the cable. The trunk cable-connector assembly comprises: a second cable including a plurality of second subunits, each of the second subunits comprising a plurality of twisted pairs of conductors; a plug attached to one end of the second cable and connected with the jack of the extension trunk cable; and a plurality of RJ-45 connectors attached to subunits at an opposite end of the second cable.

Abstract: A datacommunication interconnection system includes (a) an extension trunk cable-connector assembly and (b) a trunk cable-connector assembly. The extension trunk cable-connector assembly comprises: a first cable including a plurality of first subunits, each of the first subunits comprising a plurality of twisted pairs of conductors; a jack attached to one end of the cable; and a plug attached to an opposite end of the cable. Each of the jack and the plug includes a contact for each of the conductors of the cable. The trunk cable-connector assembly comprises: a second cable including a plurality of second subunits, each of the second subunits comprising a plurality of twisted pairs of conductors; a plug attached to one end of the second cable and connected with the jack of the extension trunk cable; and a plurality of RJ-45 connectors attached to subunits at an opposite end of the second cable.

Abstract: Methods of automatically monitoring changes made to the communications connections into a server are provided. Pursuant to these methods, an identification is made that a change was made to the communications connections into the server. A determination is then made if the identified change complies with a set of pre-determined rules. If it is determined that the change does not comply with at least one of the rules in the set of pre-determined rules, then an alert is automatically issued.

Abstract: A communications system includes a plurality of patch panels, wherein each patch panel has a plurality of connector ports on a front surface thereof that are each connected to a respective communication line, and one or more optical couplers/connector ports on a rear surface thereof for linking two or more patch panels together. A cable for linking patch panels includes opposite ends and a respective connector at each end that is configured to be removably secured within a respective coupler/connector port on the rear surface. Each connector has an RFID tag attached thereto. An RF antenna is secured to each patch panel adjacent each respective coupler, and each antenna is configured to activate and read information from a cable RFID tag when a cable connector is secured within a coupler adjacent thereto.

Abstract: A datacommunications patching system includes: a mounting frame; a first module mounted in the mounting frame and including a plurality of connector ports on one side thereof and first and second connectors on another side thereof; and a backplane that is mounted in the mounting frame. The backplane electrically connects to the first module via the first connector when the first module is mounted in the mounting, frame in a first orientation. and wherein the backplane electrically connects to the first module via the second connector when the first module is mounted in the mounting frame in a second orientation that is inverted from the first orientation.

Abstract: A modular rack controller for an intelligent patching system includes a base unit comprising a processor and memory that monitor and log patch cord connectivity in the patching system, and a separate display unit comprising a user interface. The base unit and display unit are in electrical communication with each other via a patch cord, and the display unit displays patch cord connectivity information monitored by the base unit. The rack controller may include a separate Ethernet interface unit that allows the rack controller to communicate with other rack controllers. A mounting bracket having front and rear sides is mounted to a patch panel rack. The display unit is secured to the front side of the mounting bracket and the base unit is secured to the rear side of the mounting bracket. The mounting bracket may have a hinge that pivots the display unit relative to a patch panel rack.

Abstract: A communications patching system includes a patch panel having a plurality of connector ports on a side thereof, and a sensor module secured to the patch panel side. The sensor module includes a plurality of pairs of IR emitters and sensors, with each emitter/sensor pair located adjacent to a respective one of the connector ports. Each emitter/sensor pair is configured to detect insertion and removal of a patch cord connector from a respective connector port. The sensor module includes a housing and a printed circuit board (PCB) secured to the housing. The IR emitters and sensors are electrically connected to the PCB, and the PCB includes a processor and memory for controlling the IR emitters and sensors.

Abstract: Methods of determining patch cord connectivity information include receiving, at each of a plurality of RFID readers, a signal from an RFID tag that is associated with a first patch cord and then, identifying the one of a plurality of connector ports that the first patch cord is connected to based at least in part on respective strengths of the signals received at each of the plurality of RFID readers. RFID triangulation systems and methods of calibrating such systems are also provided.

Abstract: Patch panels are provided that include a mounting frame and a plurality of MPO-to-MPO couplers that are mounted on the mounting frame. Each MPO-to-MPO coupler includes a first connector port that is accessible from the front side of the patch panel and a second connector port that is accessible from the rear side of the patch panel. The patch panels also include a first set of antennas, where each antenna from the first set of antennas is adjacent the first connector port of a respective one of the MPO-to-MPO couplers and a second set of antennas, where each antenna from the second set of antennas is adjacent the second connector port of a respective one of the MPO-to-MPO couplers.

Abstract: An equipment mounting system for rack-mounted devices, such as patch panels, servers, etc., includes a frame that is configured to support equipment mounted thereto in a plurality of spaced-apart mounting locations. A plurality of RF antennas are secured to the frame in spaced-apart relationship such that each antenna is located at a respective mounting location. Each RF antenna is configured to activate and read information from an RFID tag attached to equipment mounted to the frame at a respective mounting location. A microprocessor is configured to selectively activate each antenna to identify the presence of an RFID tag in close proximity to the RF antenna and to read information from an RFID tag. The microprocessor is configured to receive RFID tag information such as equipment identification information and location information, from each antenna and transmit received RFID tag information to a remote device.

Abstract: Communications patching systems may include one or more patch panels, each of which has plurality of connector ports. A plurality of antennas are provided. Each antenna may be associated with a specific connector port. A radio frequency identification (“RFID”) transceiver and a controller are also provided. A switching circuit is coupled between an output of the RFID transceiver and the plurality of antennas. This switching circuit includes a plurality of switches that are configured to selectively couple one of the plurality of antennas to the output of the RFID transceiver under the control of the controller.

Abstract: A telecommunications patching system includes a patch panel comprising a plurality of connector ports and a plurality of patch cords configured to selectively interconnect pairs of the connector ports. Each patch cord has opposite ends and a respective connector secured to each end that is configured to be removably secured within a connector port. The connectors of a respective patch cord have the same unique identifier associated therewith. A first sensor is located at each connector port and detects when a patch cord connector is inserted within, and removed from, a respective connector port. A second sensor is located at each connector port and reads the identifier of a patch cord connector inserted within a respective connector port. The first and second sensors are in communication with a controller that monitors and logs patch cord interconnections with the connector ports.

Abstract: A microprocessor-controlled coin telephone station includes apparatus that enables it to provide dialed telecommunications service and accept payment therefor--which is its primary function. The coin telephone station further includes apparatus for automatically dialing predetermined telephone numbers, automatically answering incoming telephone calls, and apparatus for monitoring conditions associated with its primary function in order to be a participating member of a hierarchal reporting network--which is its secondary function. In order to carry out the secondary function, the coin telephone station stores operating instructions which cause it to operate as either a Master or a Slave station within the hierarchal network.