Disclosed are a distribution transformer terminal and a method for monitoring a state of a distribution transformer court device. The distribution transformer terminal includes an ARM core processor, a carrier communication module connected to a court device, a sub-G wireless communication module connected to the court device and a GPS module connected to the court device. The ARM core processor is connected to the carrier communication module, the sub-G wireless communication module and the GPS module. The ARM core processor is configured to identify a phase of the court device and a court to which the court device belongs acquire an operating state and fault information of the court device through the sub-G wireless communication module, and acquire geographical location information of the court device through the GPS module.

Selecting a communication route between a first and a second node device of a mesh electrical supply network using powerline and/or radio-frequency communications is described. A route cost is obtained for each possible communication route. A communication route of the lowest route cost is selected. For a given route, the route cost is the sum of the link costs between successive node devices on the route, the link cost between two successive node devices is a weighted sum between a maximum value from a link cost in a forward direction and a link cost in a backward direction and a ratio between a number of active routes and a maximum number of active routes. A link cost in a given direction depends on the cost of the link, in the given direction, calculated for each frequency band of frequency bands used by the two successive node devices for communicating.

Embodiments of methods and systems for supporting coexistence of multiple technologies in a Power Line Communication (PLC) network are disclosed. A long coexistence preamble sequence may be transmitted by a device that has been forced to back off the PLC channel multiple times. The long coexistence sequence provides a way for the device to request channel access from devices on the channel using other technology. The device may transmit a data packet after transmitting the long coexistence preamble sequence. A network duty cycle time may also be defined as a maximum allowed duration for nodes of the same network to access the channel. When the network duty cycle time occurs, all nodes will back off the channel for a duty cycle extended inter frame space before transmitting again. The long coexistence preamble sequence and the network duty cycle time may be used together.

Disclosed is a device for selectively receiving data broadcast in a network. The device includes first unit for receiving configuration data transmitted in point-to-point mode, second unit for receiving data broadcast by at least one transmitter, by radio and/or by power-line communication, a digital processing sub-assembly, at least one memory for storing at least one datum determining the selectivity of the broadcast, a low-voltage power supply sub-assembly supplied by an energy source and at least one program for determining whether data received by the second unit should be used or ignored by the device, as a function of previously stored data. Also disclosed is a system for allowing devices to selectively receive data broadcast in a network. Additionally disclosed is a method for allowing a device to selectively receive data broadcast in a network.

Techniques for computing electrical phase of electrical metering devices are described. In an example, data indicating zero-crossing times at first and second metering devices is obtained. A time-difference between the zero-crossing times may be determined. In a first example, the time-difference may be based at least in part on calculations involving a first value of a first free-run timer on a first metering device, a second value of a second free-run timer on a second metering device, and a time of a transmission between the metering devices. In a second example, the time-difference may be based at least in part on calculations involving a start or end time of a time-slot of a spread spectrum radio frequency transmission scheme. A phase difference between the first zero-crossing and the second zero-crossing may be determined, based at least in part on the determined time-difference.

A system, referred to as a reading system, used in an automated metering management system in the context of a fluid-distribution service comprising a plurality of fluid meters is disclosed. The first communication module in accordance with a wireless communication standard is used by each fluid meter and a second communication module suitable for communicating by powerline with a data concentrator via a first network, said data concentrator communicating with a management entity of the automated metering management system via a second network. Instancing an application emulating a virtual fluid meter able to communicate directly with the data concentrator for each fluid meter in the plurality, and, for each fluid meter in the plurality, the corresponding virtual fluid meter takes responsibility for retransmitting information representing a fluid-consumption reading, said information having been supplied to the reading system by said fluid meter to the management entity via the data concentrator.

A communication device in a network may receive a stream of frames from the network, in which each frame includes one or more beacon packets. A communication protocol being used by the network may be identified by tracking a preselected field within a sequence of beacon packets, in which the preselected field varies in a first known manner for a first protocol and in a second known manner for a second protocol. The communication device may then join to the network using the identified communication protocol to transmit and receive data.

Aspects of the subject disclosure may include, for example, receiving wirelessly a first transmission of data from a network interface device, wherein the network interface device includes a receiver and a transmitter. The network interface device receives, via the receiver, electromagnetic waves that propagate on a surface of a dielectric transmission medium. The network interface device converts, via the receiver, the electromagnetic waves to an electrical signal, and transmits, via the transmitter, a first transmission of the data based on the electrical signal. A determination is made that the data is to be directed towards a recipient device connected to at least one electrical circuit and, based on the determination, a second transmission of the data is initiated as a power line communication transmission of a utility power line via the at least one electrical circuit. Other embodiments are disclosed.

Systems and methods for setting a carrier-sensing mechanism in a PLC node are disclosed. In a PLC standard, coexistence is achieved by having the nodes detect a common preamble and backing off by a Coexistence InterFrame Space (cEIFS) time period to help the node to avoid interfering with the other technologies. In one embodiment, a PHY primitive is sent from the PHY to the MAC know that there has been a preamble detection. A two-level indication may be usedone indication after receiving the preamble and other indication after decoding the entire frame. The MAC sets the carrier-sensing mechanism based on the preamble detection.

Embodiments include methods of powerline communications using a preamble with band extension is provided. A method may include receiving a packet data unit PDU. Bit-level repetition is applied to at least a portion of the PDU to create a repeated portion. Interleaving is performed per a subchannel. Pilot tones are inserted in the interleaved portion. Each data tone is modulated with respect to a nearest one of the inserted pilot tones. The PDU is transmitted over a power line.