In generating a mask signal to be used when a clock signal embedded in an interface signal is recovered, the mask signal may be generated by compensating for a processing delay time occurring in a mask signal generation circuit, thereby reducing the inaccuracy of the mask signal due to the processing delay time.

Aspects described herein include devices and methods for phase tracking and correction using sampling. One aspect includes a wireless communication apparatus having an analog 1-bit sampler configured to sample a phase locked loop (PLL) output signal using a PLL reference clock to generate 1-bit samples and a digital phase computation and control circuit configured to receive the 1-bit samples from the analog 1-bit sampler and apply phase corrections to the PLL based on a phase error derived from the 1-bit samples.

Disclosed is a baud rate tracking and compensation apparatus comprising: a clock generating component generating a clock; a sampling circuit sampling a reception signal according to the clock and thereby generating a sampled result, and the sampling circuit generating a transition notification signal when the sampled result indicates a transition of the reception signal; a clock counting circuit counting cycles of the clock between a first transition of the reception signal and a second transition of the reception signal according to the clock and the transition notification signal; a bit counting circuit counting bit(s) between the first transition and the second transition according to the clock and a bit cycle; and a calculation circuit dividing the number of the cycles by the number of the bit(s) to obtain a calculation value, and then updating the bit cycle according to the calculation value.

To detect an error in pulse width in a communication scheme that identifies a start position of a message or expresses a data value using a pulse width of a pulse included in the message, provided is a receiving apparatus including a receiving section that receives a message including a synchronization pulse having a predetermined pulse width and a first data pulse having a pulse width corresponding to a value of first data; and an error detecting section that detects an error in response to the number of non-synchronization pulses that are consecutive after the synchronization pulse being outside a predetermined number range.

A communication device includes a receiver configured to receive a signal, a sampler configured to sample the signal for each digital value of the predefined sequence of digital values in the signal, a memory configured to store a table giving, for each of a plurality of combinations of one or more preceding first digital values and a following second digital value, a threshold for a signal level to detect the second digital value, an initializer configured to, for a combination in a subset of the plurality of combinations, initialize the table based on a sample of the signal for the second value, and for a combination outside of the subset, select a combination from the subset and initialize the table based on a sample of the signal for the second value of the selected combination.

A first communication device receives an analog receive signal via a communication medium. An ADC of the first communication device converts the analog receive signal to a digital receive signal. Logic circuitry of the first communication device detects a plurality of timing signals from a second communication device based on analyzing the digital receive signal. The logic circuitry adjusts a sampling phase of the ADC in connection with at least some of the timing signals so that the ADC is using different sampling phases when different ones of the timing signals are detected. The logic circuitry determines timing information based on the detection of the plurality of timing signals when the ADC is using different sampling phases when different ones of the timing signals are detected. The first communication device determines a time of flight between the first communication device and the second communication device based on the timing information.

The purpose of the present invention is to cause a reception side communication device to appropriately detect a start bit. A serial communication unit (100), which transmits serial data by a combination of a high level signal and a low level signal, is provided with: a serial communication part (111) that provides the start bit on the head of the serial data, and transmits the high level signal in a prescribed duration just before the start bit; and a duration setting part (113) that sets the duration.

A data transmission method includes, detecting an incoming link training sequence that is transmitted from an upstream transmitter, generating a marker indicating a timing location of a word included in the incoming link training sequence, generating a self link training sequence based on a local reference clock, adjusting a time difference in the incoming link training sequence and the self link training sequence, and retransmitting an incoming bit stream based on the self link training sequence being matched to the incoming link training sequence.

A receiver circuit includes a transition density detector circuit that generates a transition density signal based on a comparison between a transition density of data words to a transition density threshold. The receiver circuit also includes a bit shift and pattern detector circuit that bit shifts one of the data words to generate bit shifted data in response to the transition density signal indicating that the transition density of the data words has reached the transition density threshold. The bit shift and pattern detector circuit counts a number of bits shifts performed on the bit shifted data to locate a synchronization character. The receiver circuit also includes a word alignment circuit that bit shifts the data words by the number of bits shifts to generate word aligned data.

A communication device includes a sampler configured to sample an input signal, wherein the sampler is configured to generate a sampled value for each sampling time of a sequence of sampling times, a sequence value generator configured to generate an output value for each sampling time of the sequence of sampling times based on the sampled values, wherein the sequence value generator is configured to set the output value for a sampling time based on the sampled value for the sampling time and based on a limitation of the difference between the output value for the sampling time and the output value for the preceding sampling time in the sequence of sampling times, and an edge detector configured to detect an edge in the input signal based on the output values.