A semiconductor device includes a reception data input terminal configured such that reception data, which is serial data, is input; a transmission data output terminal configured such that transmission data, which is serial data, is output; and a communication part configured to receive the reception data and transmit the transmission data, wherein the communication part includes: a counter; and a synchronization part configured to monitor the transmission data if the semiconductor device is other than a target device set in the reception data, and reset a count by the counter upon detecting a stop bit and a start bit at frame switching in the transmission data.

An integrated circuit communication architecture is provided and includes a clock lane, a clock divider, and a first de-skew circuit. The clock lane is configured to send a clock signal at a first rate from a first chip to a second chip. The clock divider is on the second chip and is configured to receive the clock signal sent via the clock lane and to create and send a first divided clock signal and a second divided clock signal from the received clock signal. The divided clock signals are sent at reduced rates compared to the first rate. The clock divider maintains current mode logic properties for the divided clock signals. The first de-skew circuit is configured to receive and process the divided clock signals to allow for sampling of data transmitted from the first chip to the second chip.

Methods and systems are described for receiving a plurality of signals in a signaling interval at a multi-input comparator (MIC), and responsively generating an analog linear combination of the received signals, amplifying the analog linear combination of the received signals using an integration stage, receiving the amplified differential voltage at two multi-phase receivers, each multi-phase receiver comprising one or more processing slices, each multi-phase receiver operating in a multi-phase processing path for processing the amplified differential voltage, wherein processing the amplified differential voltage includes generating output data decisions and phase-error information using a first multi-phase receiver of the two multi-phase receivers and selectively adjusting local speculative decision feedback equalization (DFE) slicing offsets of a second multi-phase receiver of the two multi-phase receivers according to the output data decisions generated by the first multi-phase receiver.

Methods and systems are described for receiving a plurality of signals in a signaling interval at a multi-input comparator (MIC), and responsively generating an analog linear combination of the received signals, amplifying the analog linear combination of the received signals using an integration stage, receiving the amplified differential voltage at two multi-phase receivers, each multi-phase receiver comprising one or more processing slices, each multi-phase receiver operating in a multi-phase processing path for processing the amplified differential voltage, wherein processing the amplified differential voltage includes generating output data decisions and phase-error information using a first multi-phase receiver of the two multi-phase receivers and selectively adjusting local speculative decision feedback equalization (DFE) slicing offsets of a second multi-phase receiver of the two multi-phase receivers according to the output data decisions generated by the first multi-phase receiver.

An injection locked frequency divider includes a mixer circuit and a filter circuit. The mixer circuit includes two mixer units and two inductors. The mixer units mix a differential input voltage signal with a reference signal to output a differential current signal. The inductors cooperatively receive the differential current signal from the mixer units. The filter circuit is connected to the inductors, and filters the differential current signal to output a filtered differential voltage signal.

A system includes a first device, coupled to a link, which transmits a signal having a repeating pattern on one or more paths of the link. The system includes a second device coupled to the link and including one or more circuits and a time-to-digital converter (TDC). The second device is to receive at the one or more circuits the signal. The second device is to determine, by the TDC, a current duty cycle of the signal, the current duty cycle having a first duration associated with a first portion of the signal and a second duration associated with a second portion of the signal. The second device is further to determine the current duty cycle fails to satisfy a condition associated with a target duty cycle in response to determining the current duty cycle of the signal and adjust the current duty cycle to obtain an adjusted duty cycle.

A transmitter circuit receives a PWM input signal and a clock signal. A logic circuit generates a control signal as a function of the clock signal. The control signal is normally set to high, and is periodically set to low for a transmission time interval when an edge is detected in the clock signal. The transmission time interval is shorter than a half clock period of the clock signal. A tri-state transmitter receives the PWM input signal and the control signal, and produces first and a second output signals at first and second transmitter output nodes, respectively. The output signals have a voltage swing between a positive voltage and a reference voltage. An output control circuit is sensitive to the control signal and is coupled to the first and second transmitter output nodes.

A transmitter circuit receives a PWM input signal and a clock signal. A logic circuit generates a control signal as a function of the clock signal. The control signal is normally set to high, and is periodically set to low for a transmission time interval when an edge is detected in the clock signal. The transmission time interval is shorter than a half clock period of the clock signal. A tri-state transmitter receives the PWM input signal and the control signal, and produces first and a second output signals at first and second transmitter output nodes, respectively. The output signals have a voltage swing between a positive voltage and a reference voltage. An output control circuit is sensitive to the control signal and is coupled to the first and second transmitter output nodes.

Methods and systems are described for generating, with a local oscillator and an adjustable phase interpolator, a data-sampling clock and a variable-phase-offset eye-measurement clock, forming a received data signal using a multi-input comparator, generating, using a data slicer and the data sampling clock, a receive sample of the received data signal, and generating, using at least one eye slicer and the variable-phase-offset eye-measurement clock, a plurality of eye characteristic measurements by adjusting a sampling threshold of the at least one eye slicer and a phase offset of the variable-phase-offset eye-measurement clock.

Methods and systems are described for generating, with a local oscillator and an adjustable phase interpolator, a data-sampling clock and a variable-phase-offset eye-measurement clock, forming a received data signal using a multi-input comparator, generating, using a data slicer and the data sampling clock, a receive sample of the received data signal, and generating, using at least one eye slicer and the variable-phase-offset eye-measurement clock, a plurality of eye characteristic measurements by adjusting a sampling threshold of the at least one eye slicer and a phase offset of the variable-phase-offset eye-measurement clock.