A network distribution method applied to a Power Line Communication (PLC) sub-device includes: acquiring Wi-Fi configuration information from a PLC parent device through a power line in response to the PLC sub-device to be distributed accessing the power line; and performing Wi-Fi configuration on the PLC sub-device based on the configuration information. By connecting the power line, the PLC parent device sends the Wi-Fi configuration information to the PLC sub-device to be distributed, and the PLC sub-device performs network distribution based on the Wi-Fi configuration information and the router, thereby simplifying the network distribution process of the smart devices, the user only needs to electrically connect the PLC sub-device to be distributed to the power line through the socket to implement the network distribution process.

A network distribution method applied to a Power Line Communication (PLC) sub-device includes: acquiring Wi-Fi configuration information from a PLC parent device through a power line in response to the PLC sub-device to be distributed accessing the power line; and performing Wi-Fi configuration on the PLC sub-device based on the configuration information. By connecting the power line, the PLC parent device sends the Wi-Fi configuration information to the PLC sub-device to be distributed, and the PLC sub-device performs network distribution based on the Wi-Fi configuration information and the router, thereby simplifying the network distribution process of the smart devices, the user only needs to electrically connect the PLC sub-device to be distributed to the power line through the socket to implement the network distribution process.

An electronic system for a firearm includes a power source, one or more electrical conductors electrically connected to receive power from the power source, and a plurality of electronic devices. Each electronic device has an electrical input configured to receive power from the one or more electrical conductors to power the electronic device. A communication device is configured for data communication across the one or more electrical conductors. In some embodiments data can be communicated at rates greater than 10 Mbps. Some embodiments utilize multi-frequency encoding, such as orthogonal frequency-division multiplexing. Some embodiments include a data communication device with a lower data communication rate and another data communication device with a higher data communication rate, and can selectively communicate through either data communication device. A method of communicating between electronic devices connected to a firearm includes powering a plurality of electronic devices connected to a firearm from a power source through one or more electrical conductors, and communicating data between the plurality of electronic devices across the one or more electrical conductors.

An electronic system for a firearm includes a power source, one or more electrical conductors electrically connected to receive power from the power source, and a plurality of electronic devices. Each electronic device has an electrical input configured to receive power from the one or more electrical conductors to power the electronic device. A communication device is configured for data communication across the one or more electrical conductors. In some embodiments data can be communicated at rates greater than 10 Mbps. Some embodiments utilize multi-frequency encoding, such as orthogonal frequency-division multiplexing. Some embodiments include a data communication device with a lower data communication rate and another data communication device with a higher data communication rate, and can selectively communicate through either data communication device. A method of communicating between electronic devices connected to a firearm includes powering a plurality of electronic devices connected to a firearm from a power source through one or more electrical conductors, and communicating data between the plurality of electronic devices across the one or more electrical conductors.

A device comprises a plurality of temperature sensing elements and a control module. The plurality of temperature sensing elements are each arranged proximal to a respective current carrying blade of an electrical plug. The control module receives, from the plurality of temperature sensing elements, a plurality of temperature signals that each indicate a temperature associated with the respective current carrying blades of the electrical plug. The control module also determines a temperature condition of the electrical plug based on the plurality of temperature signals. The control module also communicates an indication of the temperature condition of the electrical plug via an electrical power carrying conductor that supplies electrical power via the electrical plug.

Communication systems and methods over direct current (DC) power conductors to remote subunits may include interrupt windows in a power signal on a DC power conductor for safety reasons. The timing of rising and falling edges of the interrupt window may be modified, thereby changing the duration, period, or position within a period of the interrupt window. In effect, interrupt windows within the DC power signal may be pulse width modulated to send data between a power source and one or more subunits. Pulse width modulation (PWM) of the DC power signal preserves the safety features, but allows data and/or commands to be transferred between the power source and any subunits.

Disclosed is a signal conductor formed as a metal oxide varistor (MOV), the MOV having a first MOV and a second MOV separated by an insulator. In some embodiments, the disclosed signal conductor may be used in a system communicably coupled to a power transmission distribution network, the system capable of launching transverse electromagnetic waves onto a transmission line, where the electromagnetic waves propagating a data signal conveyed to the system by the MOV.

Disclosed is a signal conductor formed as a metal oxide varistor (MOV), the MOV having a first MOV and a second MOV separated by an insulator. In some embodiments, the disclosed signal conductor may be used in a system communicably coupled to a power transmission distribution network, the system capable of launching transverse electromagnetic waves onto a transmission line, where the electromagnetic waves propagating a data signal conveyed to the system by the MOV.

Signal correction circuitry is described that improves the integrity of data transmitted over a serial data interface without interrupting the communication between the connected devices. The signal correction circuitry includes edge correction circuitry that speeds up the rising and falling edges of the data signal(s). The signal correction circuitry also includes DC compensation circuitry that boosts the level(s) of the data signal(s).

Aspects relate to a charging station configured to transfer power between an electric aircraft and a power grid via a charging connection. In one or more embodiments, charging station may communicate with the power grid and/or electric aircraft via a communication network. For example, the charging station may be configured to receive a supply request from a power grid or a demand request from an electric aircraft and subsequently generate a control signal that transfers electrical power between the power grid and the electric aircraft via the charging connection.