A device includes an input converter, an output converter, and a controller. The input converter is electrically coupled to an electrical meter and an energy production array. The output converter is electrically coupled to the energy production array and a load. The controller is communicatively coupled to the input converter, the output converter, the energy production array, and the load. The input converter and the output converter are positioned between the electrical meter and the load.

A device includes an input converter, an output converter, and a controller. The input converter is electrically coupled to an electrical meter and an energy production array. The output converter is electrically coupled to the energy production array and a load. The controller is communicatively coupled to the input converter, the output converter, the energy production array, and the load. The input converter and the output converter are positioned between the electrical meter and the load.

Disclosed are one or more preferred geometric configurations for a device communicably coupled to a power transmission line and capable of launching transverse electromagnetic waves onto the transmission line. The waves propagate data received from a data source and may include a reflector and a coupler adjacent to each other through a transverse magnetic wave that propagates longitudinally along the surface of the transmission line.

Disclosed are one or more preferred geometric configurations for a device communicably coupled to a power transmission line and capable of launching transverse electromagnetic waves onto the transmission line. The waves propagate data received from a data source and may include a reflector and a coupler adjacent to each other through a transverse magnetic wave that propagates longitudinally along the surface of the transmission line.

Power cords are provided. A power cord includes measurement circuitry configured to measure electrical energy consumption by an apparatus that is connected to the power cord. The power cord also includes first transceiver circuitry configured to transmit data regarding the measured electrical energy consumption to second transceiver circuitry that is spaced apart from the power cord. Related hardwired apparatuses and methods are also provided.

A dual cavity, low power, outdoor combination line amplifier package for cable telecommunication systems is disclosed. It comprises: a dual-cavity main frame, cast in one piece and sectioned into an upper cavity and a lower cavity; a hardline entry cover, having a hardline receptacle PCB with a power supply fixed thereon, electrically and environmentally sealing on one side of the upper cavity; a tap plate cover, having a tap plate PCB fixed thereon and mounted with a plurality of taps, electrically and environmentally sealing on the other side of the upper cavity with the taps facing externally; a gain module heatsink cover, having a gain module PCB and a passive PCB fixed thereon, electrically and environmentally sealing on one side of the lower cavity; and a smart app accessories cover, having a smart access cover PCB fixed thereon, electrically and environmentally sealing on the other side of the lower cavity.

A data transmission system and an operation method thereof are provided. The data transmission system includes a host, a first device and a second device. The host is configured to set a voltage base of a transmission signal, and configured to pull down or up the transmission signal based on the voltage base of the transmission signal to form a plurality of glitches. The first device is connected to the host to receive the transmission signal. The first device obtains a digital content of the transmission signal according to the glitches, if the voltage base of the transmission signal is set as a first base. The second device is connected to the host to receive the transmission signal. The second device obtains the digital content of the transmission signal according to the glitches, if the voltage base of the transmission signal is set as a second base.

Disclosed here are systems and methods for controlling an irrigation system using a two-wire electrical path. The system includes a controller, decoders, and sensors all connected by a two-wire wired connection. The controller controls the decoders and provides parameters to the sensors in an open-loop operation mode. The sensors may control one or more of the decoders in a closed-loop operation mode. The system may further operate in a hybrid operation mode providing both open- and closed-loop operation. The various components of the system communicate using a power line communication protocol which places data on a frequency or bandwidth separate from the power signal.

Embodiments of this application provide a communication method, apparatus, and system. In the method, after a first remote radio unit (RRU) determines that a link between the first RRU and a baseband unit (BBU) is in an abnormal state, the first RRU sends information about the first RRU and/or information about an optical module connected to the first RRU to at least one second RRU by using a power line communication (PLC) module in the first RRU. The first RRU is connected to the at least one second RRU by using a power line, and a PLC module is also disposed in the at least one second RRU.

Techniques are provided for detecting a fault across a pair of lines. Pulse power is applied across the pair of lines. The pulse power comprises alternating pulse on-time intervals and pulse off-time intervals. During a pulse off-time interval, a resistor is connected across the pair of lines and then disconnected when a voltage across the pair of lines reaches a first droop percentage in a first period of time. After disconnecting the resistor, it is determined whether the voltage across the pair of lines droops at least a second droop percentage within a second period of time that begins after the first period of time. Occurrence of a line-to-line fault across the pair of lines is determined when the voltage across the pair of lines droops by at least the second droop percentage or more within the second period of time.