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.

Disclosed are techniques to regenerate SYNC bits of a High-Speed data packet lost by the transmission envelope detector of a repeater/hub that interconnects electronic devices compliant with Universal Serial Bus (USB) Specification Revision 2.0 or higher. A physical layer logic (PHY) of a first port of the repeater/hub receives a High-Speed data packet to store a recovered bit stream into an elastic buffer. The recovered bit stream may lose some SYNC bits at the beginning of the SYNC pattern. The repeater/hub reads the recovered bit stream from the elastic buffer for transmission through the PHY of a second port. If the end of the SYNC is read before a programmable number of SYNC bits have been transmitted, the repeater/hub generates additional SYNC bits for transmission until the programmable number of SYNC bits are transmitted. The repeater/hub then resumes transmitting the rest of the High-Speed data packet starting from the payload.

Disclosed are techniques to regenerate SYNC bits of a High-Speed data packet lost by the transmission envelope detector of a repeater/hub that interconnects electronic devices compliant with Universal Serial Bus (USB) Specification Revision 2.0 or higher. A physical layer logic (PHY) of a first port of the repeater/hub receives a High-Speed data packet to store a recovered bit stream into an elastic buffer. The recovered bit stream may lose some SYNC bits at the beginning of the SYNC pattern. The repeater/hub reads the recovered bit stream from the elastic buffer for transmission through the PHY of a second port. If the end of the SYNC is read before a programmable number of SYNC bits have been transmitted, the repeater/hub generates additional SYNC bits for transmission until the programmable number of SYNC bits are transmitted. The repeater/hub then resumes transmitting the rest of the High-Speed data packet starting from the payload.

A transmission method for transmitting a packet from a first node device to a second node device of an electrical supply network, the transmission method includes the following steps performed by the first node device: transmitting the IP packet by radio frequency in the case where a level of use by the first node device of the transmission by radio frequency calculated on a sliding time window with respect to a maximum use time is below a first threshold, the first threshold being below a second threshold beyond which any transmission by radio frequency is interrupted; transmitting the IP packet by powerline otherwise, and, in the case where the powerline transmission fails, transmitting the IP packet by radio frequency in the case where the level of use is below the second threshold.

A transmission method for transmitting a fragment of an IP packet from a first node device to a third node device through a second node device. The first and second node devices are configured for communicating by powerline and by radio frequency. The second and third node devices can communicate only using a single communication medium from powerline and radio frequency. A first fragment sent by said first node device either by powerline or by radio frequency is received. An acknowledgement message is sent by to said first node device using a second communication medium selected from powerline and radio frequency so that it is different from said single medium. Then said first fragment is transmitted to said third node device using said single communication medium.

Aspects of the subject disclosure may include, a device having an envelope detector, an oscillator, a switch driver, a processing system including a processor; and a memory that stores executable instructions that, when executed by the processing system, facilitate performance of operations, the operations of comparing a first signal received from the envelope detector and a second signal received from the oscillator within a high probability interval, thereby generating a valid detection; and activating the switch driver responsive to the valid detection. Other embodiments are disclosed.

Aspects of the subject disclosure may include, a device having an envelope detector, an oscillator, a switch driver, a processing system including a processor; and a memory that stores executable instructions that, when executed by the processing system, facilitate performance of operations, the operations of comparing a first signal received from the envelope detector and a second signal received from the oscillator within a high probability interval, thereby generating a valid detection; and activating the switch driver responsive to the valid detection. Other embodiments are disclosed.

In one embodiment, a switched amplifier is provided to amplify a data transmission. The switched amplifier may use a control signal that is received via a control signal channel in a transmission cable. Also, the switched amplifier may detect signal power to determine whether the data transmission is received at one of a first port and a second port. Data transmissions via the data transmission channel occur in a first direction and a second direction in a same frequency range in a time division multiplex (TDD) mode. Also, the control signal and data transmission are diverted from the transmission cable that transmits a type of signal different from the control signal and the data transmission. The switched amplifier is controlled based on the control signal or the signal power detected. The amplified signal is diverted in the first direction or the second direction via the data transmission channel back to the transmission cable.

A resident remotely operated vehicle may be deployed subsea by deploying a remotely operated vehicle (ROV) (200) configured to be disposed and remain resident subsea for an extended time where the ROV comprises an ROV electrical power connector port (202) to be operatively connected to an electrical power supply (700) dedicated to the ROV. An RTMS configured to be disposed subsea for an extended time is also deployed subsea (210), typically proximate the ROV. A subsea docking hub subsea is also deployed subsea proximate the RTMS and operatively connected to the ROV and the RTMS. In addition, an umbilical is connected from the subsea docking hub to a subsea structure and a signal supplied from the subsea structure to the ROV.