Abstract: Intelligent patch panels support patch cord management in communications networks. Modular patch panels can be connected to one another for the purposes of sharing power and also for the purposes of monitoring patch cord connections and reporting the status of patch cord connections to a network management system. Each port of an intelligent patch panel may be provided with out-of-band contacts to allow for monitoring and reporting of patch cord connectivity information. According to one embodiment, out-of-band contacts send identification information regarding their associated patch panel ports along a ninth wire of a patch cord.

Abstract: A method and apparatus are provided for monitoring the physical topology of a network on a real-time basis. For patch panel systems, the approach is based upon a distributed architecture that may be modularly scalable and may allow each patch panel to determine port level connectivity by independently monitoring an out-of-band channel supported by each respective port. The approach provides improved real-time reporting of patch panel connectivity with reduced cabling complexity, increased reliability and decreased maintenance costs. The approach is capable of determining the physical equipment and/or physical location information associated with the respective patch panel ports, in real-time, and thereby provide physical network topology information associated with patch cord connections. The approach is compatible with multipurpose network management systems.

Abstract: A method and apparatus are provided for monitoring and reporting cable connectivity such as patch panel port-level connectivity on a real-time basis. For patch panel systems, the approach is based upon a distributed architecture that may be modularly scalable and may reduce, if not eliminate, the need for a centralized signal processor and complex cabling between patch panels and the centralized signal processor. Each patch panel may determine port level connectivity independently. Polling delays and polling-related overhead processing may be reduced or eliminated by supporting real-time monitoring of port connectivity at the port level. The approach provides improved real-time reporting of patch panel connectivity with reduced cabling complexity, increased reliability, and decreased maintenance costs. In addition, the approach is compatible with (i.e., may communicate with and be controlled by) a multipurpose network management system (NMS). In addition, a compatible revision system is provided.

Abstract: A communication network device and corresponding patch field system are disclosed. The device includes a port module, ports, and an appliqué attached to a face of the port module. The appliqué includes a printed circuit board (PCB) with conductive pads. A patch cord connects the device with an intelligent patch panel. The patch cord contains at least one system wire. The patch panel is adapted to measure a resistance associated with each port via the system wire. An open circuit indicates that no patch cord is attached to the port, a resistance within a first range indicates that the patch cord is attached only to the port of the intelligent patch panel, and a resistance within a second range less than the first range indicates that the patch cord connects the intelligent patch panel and the device.

Abstract: Intelligent patch panels support patch cord management in communications networks. Modular patch panels can be connected to one another for the purposes of sharing power and also for the purposes of monitoring patch cord connections and reporting the status of patch cord connections to a network management system. Each port of an intelligent patch panel may be provided with out-of-band contacts to allow for monitoring and reporting of patch cord connectivity information. According to one embodiment, out-of-band contacts send identification information regarding their associated patch panel ports along a ninth wire of a patch cord.

Abstract: An active jack, which is a powered device, is installed as the network connection at a workstation which provides the capability to determine the physical location of a destination device, such as a VOIP phone, in real time. Uninterruptible power supplies may be used to provide power to network components, for example during an emergency. Power-and-data deployments are shown for powering network components and destination devices.

Abstract: A method and apparatus are provided for incorporating guided network cable Move/Add/Change (MAC) work order capability into a power patch panel. MAC work orders may be controlled and monitored using in-band signaling using, e.g., standard RJ-45 patch cords. Cable detection is performed at a port level on a real-time basis. Coordination of guided MAC operations may be performed by the patch panel, independently, or in conjunction with, or under the control of, a remote Network Management System. The patch panel may be in either an interconnect or cross-connect configuration.

Abstract: A network documentation and revision system is presented that includes first and second devices connected by a patch cord. The first device has provisioning and signal ports with corresponding contact assemblies. The second device has a switch port without a contact assembly. The patch cord has signal and control wires, a first connector that connects the signal wires into a signal port and the control wire to a corresponding contact assembly, and a second connector that connects the signal wires to the switch port and terminates the control wire. The second connector contains an indicator controlled by control circuitry, detection circuitry detecting whether the second connector is plugged into the second device, and ID circuitry providing an ID number through the first connector. Installation or removal of the patch cord is guided by indicators on the patch cord and first device without retrofit contacts being added to the second device.

Abstract: A communication network device and corresponding patch field system are disclosed. The device includes a port module, ports, and an appliqué attached to a face of the port module. The appliqué includes a printed circuit board (PCB) with conductive pads. A patch cord connects the device with an intelligent patch panel. The patch cord contains at least one system wire. The patch panel is adapted to measure a resistance associated with each port via the system wire. An open circuit indicates that no patch cord is attached to the port, a resistance within a first range indicates that the patch cord is attached only to the port of the intelligent patch panel, and a resistance within a second range less than the first range indicates that the patch cord connects the intelligent patch panel and the device.

Abstract: Systems and methods for detecting a patch cord connection are presented. The insertion of a patch cord into a device jack physically closes a circuit, thereby permitting determination of the patch cord connection. The connection of only one side of a patch cord to a jack is able to be determined. In addition, a particular jack with which a patch cord is connected is able to be determined.

Abstract: Systems and methods for decreasing alien crosstalk use enhanced patch cords for introducing additional attenuation. The enhanced patch cords are preferably shielded to reduce alien crosstalk down their lengths and also attenuate signals passing therethrough to a greater extent than standard communication patch cords. The interaction of two enhanced patch cords results in two suppression steps for alien crosstalk and only one suppression step for intended signal passing through a communication cable.

Abstract: Methods and apparatus establish and maintain reliable network cable contacts that mitigate disconnecting effects by transmitting an AC signal with a frequency that reduces the disconnecting effects. The signal frequency may be statically or dynamically selected. The approach allows the severity of a disconnecting effect to be assessed and/or monitored and may support the scheduled replacement and/or repair of network cables identified as faulty. Information related to network cable resistance may be managed within the local device and/or with assistance from a Network Management System (NMS). Physical connection reliability and resilience against disconnecting effects is further enhanced with a physical pogo-style connector that rotates to mechanically scrape and remove oxidation and debris from a conductive contact pad surface each time a physical contact is formed. Such a contact may significantly reduce the level of oxidation, oils and other debris that contribute to the disconnecting effect.

Abstract: A method and apparatus are provided for monitoring the physical topology of a network on a real-time basis. For patch panel systems, the approach is based upon a distributed architecture that may be modularly scalable and may allow each patch panel to determine port level connectivity by independently monitoring an out-of-band channel supported by each respective port. The approach provides improved real-time reporting of patch panel connectivity with reduced cabling complexity, increased reliability and decreased maintenance costs. The approach is capable of determining the physical equipment and/or physical location information associated with the respective patch panel ports, in real-time, and thereby provide physical network topology information associated with patch cord connections. The approach is compatible with multipurpose network management systems.

Abstract: Communications connectors are provided with conductive covering layers to reduce the amount of alien near-end crosstalk (ANEXT) between connectors at IDC terminals when they are installed alongside one another.

Abstract: A method and apparatus are provided for monitoring and reporting cable connectivity such as patch panel port-level connectivity on a real-time basis. For patch panel systems, the approach is based upon a distributed architecture that may be modularly scalable and may reduce, if not eliminate, the need for a centralized signal processor and complex cabling between patch panels and the centralized signal processor. Each patch panel may determine port level connectivity independently. Polling delays and polling-related overhead processing may be reduced or eliminated by supporting real-time monitoring of port connectivity at the port level. The approach provides improved real-time reporting of patch panel connectivity with reduced cabling complexity, increased reliability, and decreased maintenance costs. In addition, the approach is compatible with (i.e., may communicate with and be controlled by) a multipurpose network management system (NMS). In addition, a compatible revision system is provided.

Abstract: An network management system (NMS) architecture is disclosed that takes advantage of intelligence capable network devices for network monitoring and control. NMS functions may be distributed where possible to intelligent devices where local storage and processing may be performed. Local collection and processing of monitoring information may reduce NMS-related network traffic, permit continuing local control and operation during times of network communication disruption with the central NMS, and permit greater reliability in data collection and execution of network functions such as the enforcement of security policy at the respective intelligent devices.

Abstract: A powered communications patch panel is adapted to power network devices connected to the communications patch panel. Power is supplied to the network devices by the powered communications patch panel over the communication cabling. The powered communications patch panel may be provided with a management port to allow remote management of the patch panel via a network connection. Multiple management ports may be provided, allowing patch panels to be connected to one another in a daisy-chain configuration.

Abstract: An active jack, which is a powered device, is installed as the network connection at a workstation which provides the capability to determine the physical location of a destination device, such as a VOIP phone, in real time. Uninterruptible power supplies may be used to provide power to network components, for example during an emergency. Power-and-data deployments are shown for powering network components and destination devices.

Abstract: A system for managing and documenting a local area communications network is provided which deploys power sourcing equipment and powered devices by the use of active electronic modules, having an Ethernet controller and Power over Ethernet forwarding capabilities, as integral, managed components within the cable plant, to enhance management, documentation, security and emergency 911 aspects of the network as well as extending the physical reach of the network.

Abstract: Systems and methods for decreasing alien crosstalk use enhanced patch cords for introducing additional attenuation. The enhanced patch cords are preferably shielded to reduce alien crosstalk down their lengths and also attenuate signals passing therethrough to a greater extent than standard communication patch cords. The interaction of two enhanced patch cords results in two suppression steps for alien crosstalk and only one suppression step for intended signal passing through a communication cable.