A system includes a first device and a second device coupled to a link having one or more paths associated with transmitting a clock signal. The first device is to transmit a set of bits associated with a pattern via the one more paths. The set of bits are transmitted using a first clock signal having a first frequency less than a second frequency associated with data transmission operations. The second device is to receive the set of bits associated with the pattern, determine a number of pulses associated with the set of bits over a first period, and determine the number of pulses, associated with the set of bits, satisfies a predetermined condition relating to the number of pulses for the first period. The second device is to initiate a training of the link in response to determining the number of pulses satisfies the predetermined condition.

Systems and methods for asynchronous communication are disclosed. For example, a method for asynchronous communication includes encoding, by a transmitter circuit and according to a first clock signal, a bit sequence by converting a one-bit in the bit sequence into a first sequence and a zero-bit in the bit sequence into a second sequence. A length of the first sequence and a length of the second sequence differ by at least three bits. The method also includes communicating, by the transmitter circuit, the first sequence and the second sequence to a receiver circuit that decodes the first sequence and the second sequence according to a second clock signal that is independent of the first clock signal.

A communication system according to the present disclosure includes a first communication unit that includes a first terminal, a transmission circuit configured to transmit a clock signal via the first terminal, a first resistor inserted into a path between the first terminal and a power supply, a first switch configured to couple the power supply and the first terminal to each other by being turned on, and a first controller configured to control an operation of the first switch, and a second communication unit that includes a second terminal coupled to the first terminal of the first communication unit via a first wiring line, a reception circuit configured to receive the clock signal via the second terminal, a power storage device, a second switch configured to couple the second terminal and the power storage device to each other by being turned on, and a second controller configured to control an operation of the second switch, the second communication unit being configured to operate by supply of a voltage of the power storage device as a power supply voltage.

In some embodiments, a method for mitigating interference in a channel having multiple users can include: determining a starting angle based on a direction of a signal of interest (SOI); iteratively steering a beam away from the starting angle in opposite directions and calculating a grade of the beam; choosing the beam at a current angle as a receive beam based on the beam grade; receiving a signal using the receive beam; and decoding the SOI from one or more interfering signals using successive interference cancellation multi-user detection (SIC MUD) on the received signal.

A transmission device of the disclosure includes: a clock signal transmitting circuit that outputs a clock signal onto a clock signal line; a data signal transmitting circuit that outputs a data signal onto a data signal line; and a blanking controller that controls the clock signal transmitting circuit to output a predetermined blanking signal, in place of the clock signal, from the clock signal transmitting circuit to the clock signal line in synchronization with a blanking period of the data signal.

A transmission device of the disclosure includes: a clock signal transmitting circuit that outputs a clock signal onto a clock signal line; a data signal transmitting circuit that outputs a data signal onto a data signal line; and a blanking controller that controls the clock signal transmitting circuit to output a predetermined blanking signal, in place of the clock signal, from the clock signal transmitting circuit to the clock signal line in synchronization with a blanking period of the data signal.

A communication system according to the present disclosure includes a first communication unit that includes a first terminal, a transmission circuit configured to transmit a clock signal via the first terminal, a first resistor inserted into a path between the first terminal and a power supply, a first switch configured to couple the power supply and the first terminal to each other by being turned on, and a first controller configured to control an operation of the first switch, and a second communication unit that includes a second terminal coupled to the first terminal of the first communication unit via a first wiring line, a reception circuit configured to receive the clock signal via the second terminal, a power storage device, a second switch configured to couple the second terminal and the power storage device to each other by being turned on, and a second controller configured to control an operation of the second switch, the second communication unit being configured to operate by supply of a voltage of the power storage device as a power supply voltage.

Disclosed is a method for variably changing a communication speed by a first device when a high-speed communication request within a range supported by the first device is input from a second device during low-speed communication of the first device with a third device in the UART communication and performing data communication with the second device at the varied high speed. A method for switching, by a device, a communication speed in an universal asynchronous receiver-transmitter (UART)-based data communication includes: measuring, by an interrupt detection module of the device, a pulse width of a start bit using an interrupt signal; calculating, by a communication speed calculation module of the device, a communication speed using a time duration for which the measured pulse width is maintained; and switching, by a communication speed switching module of the device, a current communication speed of the device to the calculated communication speed.

The present specification presents a configuration technique of a field for control information in a wireless communication system. Specifically, presented is a configuration technique of a signal field including user-specific information in a wireless LAN system. A plurality of MCS techniques are applied to each field of a signal field, according to the present embodiment, and each field can be ordered according to the MCS techniques. The signal field according to the present embodiment can be used for a single user or multiple users, wherein the length of each field can be determined for blind decoding of the single user and the multiple users. The signal field according to the present embodiment can be an SIG-B field according to a wireless LAN standard.

The present specification presents a configuration technique of a field for control information in a wireless communication system. Specifically, presented is a configuration technique of a signal field including user-specific information in a wireless LAN system. A plurality of MCS techniques are applied to each field of a signal field, according to the present embodiment, and each field can be ordered according to the MCS techniques. The signal field according to the present embodiment can be used for a single user or multiple users, wherein the length of each field can be determined for blind decoding of the single user and the multiple users. The signal field according to the present embodiment can be an SIG-B field according to a wireless LAN standard.