Disclosed are techniques for removing dribble bits following the end-of-packet (EOP) of a High-Speed data packet inserted 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 include dribble bits inserted by the PHY after the EOP. The repeater/hub reads the recovered bit stream from the elastic buffer for transmission through the PHY of a second port. The repeater/hub monitors the EOP. When the EOP is detected, the repeater/hub prevents transmission of the dribble bits of the recovered bit stream following the EOP from the second port, eliminating the intended receiver of the High-Speed data packet from the complexity of dealing with dribble bits.

Disclosed are techniques for removing dribble bits following the end-of-packet (EOP) of a High-Speed data packet inserted 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 include dribble bits inserted by the PHY after the EOP. The repeater/hub reads the recovered bit stream from the elastic buffer for transmission through the PHY of a second port. The repeater/hub monitors the EOP. When the EOP is detected, the repeater/hub prevents transmission of the dribble bits of the recovered bit stream following the EOP from the second port, eliminating the intended receiver of the High-Speed data packet from the complexity of dealing with dribble bits.

The present disclosure relates to a bidirectional communication circuit for bidirectional communication between a first differential wired network and a second differential wired network and a related method of operating the bidirectional communication circuit. In particular, the present disclosure relates to a bidirectional communication circuit designed to prevent timing glitches and simultaneous transmission of data from the first network to the second network and from the second network to the first network.

An interface circuit, a string, and a system that are applied to power line communication, to lower device specifications, includes: an inverter, an optimizer group, a capacitor, a magnetic ring, power lines, and a signal line. An optimizer in the optimizer group is configured to adjust a size of a direct current output by a photovoltaic module connected to the optimizer. Two ends of the signal line passing through the magnetic ring are connected to the inverter. Two ends of a power line passing through the magnetic ring are respectively connected to the capacitor and the optimizer group. By using the foregoing interface circuit, a high voltage of a direct current output by the optimizer group is prevented from being introduced into the inverter, thereby reducing a specification requirement of a device such as a capacitor.

An interface circuit, a string, and a system that are applied to power line communication, to lower device specifications, includes: an inverter, an optimizer group, a capacitor, a magnetic ring, power lines, and a signal line. An optimizer in the optimizer group is configured to adjust a size of a direct current output by a photovoltaic module connected to the optimizer. Two ends of the signal line passing through the magnetic ring are connected to the inverter. Two ends of a power line passing through the magnetic ring are respectively connected to the capacitor and the optimizer group. By using the foregoing interface circuit, a high voltage of a direct current output by the optimizer group is prevented from being introduced into the inverter, thereby reducing a specification requirement of a device such as a capacitor.

At least some aspects of the present disclosure provide for a method. In some examples, the method includes receiving, at a circuit, data via a differential input signal, detecting a rising edge in the data received via the differential input signal, and precharging a common mode voltage (Vcm) node of the differential input signal responsive to detecting the rising edge in the data received via the differential input signal, wherein the Vcm node is a floating node.

At least some aspects of the present disclosure provide for a method. In some examples, the method includes receiving, at a circuit, data via a differential input signal, detecting a rising edge in the data received via the differential input signal, and precharging a common mode voltage (Vcm) node of the differential input signal responsive to detecting the rising edge in the data received via the differential input signal, wherein the Vcm node is a floating node.

Aspects of the subject disclosure may include, a system that facilitates directing a first electromagnetic wave to a device positioned along a transmission medium, the device facilitating a perturbation of the first electromagnetic wave, and the first electromagnetic wave having a first field intensity near an outer surface of the transmission medium, and generating, by the device, a second electromagnetic wave having a second field intensity near the outer surface of the transmission medium that is lower than the first field intensity of the first electromagnetic wave. Other embodiments are disclosed.

Aspects of the subject disclosure may include, a system that facilitates directing a first electromagnetic wave to a device positioned along a transmission medium, the device facilitating a perturbation of the first electromagnetic wave, and the first electromagnetic wave having a first field intensity near an outer surface of the transmission medium, and generating, by the device, a second electromagnetic wave having a second field intensity near the outer surface of the transmission medium that is lower than the first field intensity of the first electromagnetic wave. Other embodiments are disclosed.

The present disclosure relates to a bidirectional communication circuit for bidirectional communication between a first differential wired network and a second differential wired network and a related method of operating the bidirectional communication circuit. In particular, the present disclosure relates to a bidirectional communication circuit designed to prevent timing glitches and simultaneous transmission of data from the first network to the second network and from the second network to the first network.