A connector arrangement includes a plug nose body; a printed circuit board positioned within a cavity of the plug nose body; and a plug cover that mounts to the plug nose body to enclose the printed circuit board within the cavity. The printed circuit board includes a storage device configured to store information pertaining to the electrical segment of communications media. The plug cover defines a plurality of slotted openings through which the second contacts are exposed. A connector assembly includes a jack module and a media reading interface configured to receive the plug. A patch panel includes multiple jack modules and multiple media reading interfaces.

A powering patch panel system includes a patch panel device coupled to a power source, and including a first port that is coupled to a networking device via a first cable and a second port that is coupled to the powered device via a second cable. The patch panel device receives data that is directed to the powered device from the networking device through the first port and via the first cable, and receives power from the power source. The patch panel device then transmits both the data and a subset of the power through the second port and via the second cable to the powered device. The first port may be provided by optical-fiber-based port and the first cable may be provided by an optical-fiber-based cable, while the second port may be provided by a hybrid conductive-material/optical-fiber-based port and the second cable may be provided by a hybrid conductive-material/optical-fiber-based cable.

A method for monitoring a primary variable is carried out in a device having access to a set of sensors. The method includes the steps of receiving, from a network service, a series of forecasted values for the primary variable, each forecasted value being associated with one of a series of future time points; for at least one of the future time points, predicting a value for the primary variable using data of at least one secondary variable captured by a subset of the set of sensors, comparing the predicted value to the forecasted value associated with the future time point, and switching to a different subset of the set of sensors, if the predicted value deviates from the forecasted value with more than a specified threshold value.

In some implementations, a network device includes a housing and a set of switch cards within the housing and including a first set of connectors. A set of line cards within the housing includes a second set of connectors. The set of line cards are oriented orthogonally to the set of switch cards. A first set of power supplies and a second set of power supplies are in the housing. A midplane includes a plurality of circuit board assemblies arranged within the housing between the set of line cards and the first and second sets of power supplies to allow air to flow through the set of line cards to the set of switch cards, first set of power supplies, and second set of power supplies.

A connector arrangement includes a plug nose body; a printed circuit board positioned within a cavity of the plug nose body; and a plug cover that mounts to the plug nose body to enclose the printed circuit board within the cavity. The printed circuit board includes a storage device configured to store information pertaining to the electrical segment of communications media. The plug cover defines a plurality of slotted openings through which the second contacts are exposed. A connector assembly includes a jack module and a media reading interface configured to receive the plug. A patch panel includes multiple jack modules and multiple media reading interfaces.

ASSEMBLY AND CONTROL SYSTEM FOR ACCUMULATORS IN WORKSTATIONS, presenting a system intended for battery control in radio-base stations rack comprising a processing center which controls a switching system, batteries, electromagnetic locks and sensors, in order to prevent non-authorized actions of such batteries inside the racks from occurring.

Automated infrastructure management systems and methods document infrastructure elements within a facility, provide a comprehensive record of all network-connected equipment within a facility, and facilitate trouble shooting of network-connected equipment. An automated infrastructure management system includes a plurality of intelligent patch panels, each comprising a plurality of connector ports connected to individual communication channels of a network, a controller in communication with at least some of the intelligent patch panels that obtains connectivity information for the intelligent patch panel's ports, and management software in communication with the controller. The management software performs various functions including correlating the interconnection information for the intelligent patch panels with the physical location information for telecommunications in its database, applying energy management policies to a respective communication channel, providing real time physical location information for devices connected to communication channels to a network switch, and displaying real time physical location information of the devices.

Systems and methods for network port monitoring using low energy wireless communications are provided. In one embodiment, a device comprises: at least one port module, the at least one port module comprising one or more connector ports each configured to receive a connector of a network data cable; and a port state sensor that includes a port sensing circuit coupled to a sensor controller, wherein the port sensing circuit is configured to sense a port state for the one or more connector ports; wherein the sensor controller is configured to input the port state from the port sensing circuit, wherein in response to detecting a change in the port state from the port sensing circuit, the sensor controller wirelessly transmits port state information to a port state monitor.

Systems and methods for network port monitoring using low energy wireless communications are provided. In one embodiment, a device comprises: at least one port module, the at least one port module comprising one or more connector ports each configured to receive a connector of a network data cable; and a port state sensor that includes a port sensing circuit coupled to a sensor controller, wherein the port sensing circuit is configured to sense a port state for the one or more connector ports; wherein the sensor controller is configured to input the port state from the port sensing circuit, wherein in response to detecting a change in the port state from the port sensing circuit, the sensor controller wirelessly transmits port state information to a port state monitor.

A powering patch panel system includes a patch panel device coupled to a power source, and including a first port that is coupled to a networking device via a first cable and a second port that is coupled to the powered device via a second cable. The patch panel device receives data that is directed to the powered device from the networking device through the first port and via the first cable, and receives power from the power source. The patch panel device then transmits both the data and a subset of the power through the second port and via the second cable to the powered device. The first port may be provided by optical-fiber-based port and the first cable may be provided by an optical-fiber-based cable, while the second port may be provided by a hybrid conductive-material/optical-fiber-based port and the second cable may be provided by a hybrid conductive-material/optical-fiber-based cable.