The application relates to modular electronic apparatus (1) for distribution of RF communication signals. The apparatus comprises a chassis (2) arranged to removably receive plural modules (3), at least some of which are arranged to receive and process RF communication signals. A communication path (17) is provided for modules to communicate with each other and/or with the chassis. Plural modules received in the chassis. When a module is received in the chassis, it is arranged to broadcast a message over the communication path indicating its presence in the chassis and its type. At least one other module is arranged to adapt its behaviour in response to the message.

A network system for identifying a cable connection is provided. The network system includes a management server, a server device, and a storage device. The management server includes system-management software. The server device is connected to the management server. The server device includes a BMC configured to communicate with the system-management software of the management server. The storage device includes at least one cable port configured to receive a storage cable that connects the storage device to the server device. The cable port includes a non-volatile memory, an indicator light, and a I.sup.2C bus.

A network system for identifying a cable connection is provided. The network system includes a management server, a server device, and a storage device. The management server includes system-management software. The server device is connected to the management server. The server device includes a BMC configured to communicate with the system-management software of the management server. The storage device includes at least one cable port configured to receive a storage cable that connects the storage device to the server device. The cable port includes a non-volatile memory, an indicator light, and a I.sup.2C bus.

A connection module includes a module body and a module circuit board arrangement. The module body defines a first port and an open first end providing access to the first port. The module circuit board arrangement extends across the open first end within a peripheral boundary defined by the module body. The module circuit board arrangement includes at least a first contact set that extends into the first port of the module body; an electronic controller that is electrically connected to the first contact set; and a circuit board connector facing outwardly from the module board arrangement. Example connection modules include optical adapters and electrical jacks.

Configurations for rack connection systems are disclosed. In at least one embodiment, installation locations for one or more cables are determined and one or more indicators corresponding to installation locations are activated.

A system applied to patch panels having pairs of ports to be interconnected by the insertion of connectors provided at each end of a patch cord and carrying a passive NFC identification tag and containing a unique identity of the patch cord. A tracking module associated to each patch panel and connected to a controller device and comprising an NFC antenna associated with each panel port and a reader for processing and storing the signals that each antenna picks up from the identification tag of a connector inserted in the respective panel port. Each tracking module carries a light indicator, indicating the connection status of each port, and a button for registering the patch panel in the controller device having its operation managed, in accordance with a programmed interconnection layout, by a server.

Systems and methods for managed connectivity using local area wireless networks are provided. In certain embodiments, patching equipment in the system includes a plurality of ports configured to receive a plurality of connectors; a processing unit configured to execute instructions thereon; and a wireless communication interface, wherein the processing unit communicates connectivity information with a collection device through the wireless communication interface.

Port occupancy detection for connector panels is provided. In one embodiment, a connector panel comprises: a communications unit communicatively coupled to a network; and at least one modular port adapter assembly comprising: a plurality of communications couplers; and a plurality of port occupancy sensors each coupled to a sensor circuit. Each of the port occupancy sensors are configured to sense when the couplers are occupied. The panel communications unit obtains from the sensor circuit which of the couplers are occupied. The panel communications unit communicates port occupancy information to a gateway indicating circuit which of the couplers are occupied. A chassis including sidewalls extends between a front and a rear to define an interior, and including guides on the sidewalls. A plurality of blades mounted to the guides of the chassis, each blade including a midplane bus assembly configured to communicatively couple the sensor circuit to the panel communication unit.

A smart module (1) intended to equip a passive panel (12) of a patch enclosure comprising two lateral uprights (16, 17) bearing a series of passive panels. The module (1) comprises a body (2) in the form of a ruler and two fixing tabs (3, 4), each fixing tab (3, 4) comprising at least one hole (21-24) allowing it to be fixed rigidly to an upright (16, 17) by means of a screw, each fixing tab (3, 4) being able to be rigidly secured to an end of the body (2) by snap-fitting.

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.