Embodiments of the present disclosure provide an apparatus including: a phase detector for detecting a write frequency of a deserializer and a read frequency of a serializer, such that the phase detector outputs a first code sequence in response to the write frequency being greater than the read frequency, or a second code sequence at the rotator input in response to the write frequency being less than the read frequency; and a phase rotator for receiving the first code sequence or the second code sequence from the phase rotator to transmit a pacing signal having the read frequency to the deserializer, wherein the pacing signal causes the read frequency to increase or decrease based on whether the read frequency is different from the write frequency.

Embodiments of the present application provide a communication chip and a data processing method. The communication chip includes a plurality of synchronization modules, a set of buffer modules, and a plurality of alignment modules. The synchronization module is configured to receive data of a corresponding channel, synchronize the received data, and store the synchronized data into the buffer module; the buffer module includes a plurality of first-in-first-out queues FIFO, and the FIFO is configured to buffer the synchronized data output by the corresponding synchronization module; and the alignment module is configured to align the synchronized data of the corresponding channel in the buffer module, and combine and output the aligned data.

A method for reading data from sensors is disclosed comprising: determining a sequence of measured data over time by means of a sensor, wherein the sequence of measured data over time is generated by step-by-step changes in the measured data at input times, which are determined by an input frequency fa and have a time interval of a period 1/fa of the input frequency; reading output data from the sensor at read times, which are determined by a read frequency fs and have a time interval of a period 1/fs of the read frequency, where the read frequency fs is smaller than the input frequency fa; determining, by means of a low-pass filter of the sensor, the ratio N between the input frequency fa and the read frequency fs from the sequence over time of the numbers of input times lying between two adjacent read times.

A method of a user equipment (UE) in a communication system for obtaining and transmitting synchronization information is provided. The method includes obtaining synchronization information from a first communication network, and transmitting the synchronization information to a second communication network. The synchronization information is updated based on an obtainment time from the first communication network and a transmission time to the second communication network. The UE operates as a device-side time sensitive networking (TSN) translator (DS-TT).

A clock device includes a first phase interpolator circuit, a detector circuit, and a digital controller circuitry. The first phase interpolator circuit generates a second reference clock signal according to a first control signal and at least one first reference clock signal. The detector circuit generates an error signal according to a difference between a receiver signal and the second reference clock signal, in which the receiver signal is a receiver clock signal from a receiver circuit or an input signal that has been equalized by the receiver circuit. The digital controller circuitry generates the first control signal and a second control signal according to the error signal, and updates the second control signal according to a change of the first control signal, in which the second control signal is for generating a transmitter clock signal of a transmitter circuit.

An electronic device comprises a first circuit portion comprising one or more components, including a first counter, which are clocked by a first clock signal. The first circuit portion is arranged to receive a data stream comprising a plurality of data signals. A second circuit portion comprises one or more components clocked by a second clock signal and a second counter not clocked by the second clock signal. The first clock signal is not synchronised to the second clock signal. The second circuit portion is arranged to: receive samples of the data stream from the first circuit portion at a sample rate and to time-stamp each received sample with a count value of the second counter. The second circuit portion increments the count value of the second counter by a predetermined increment value for each received sample.

Embodiments of the present disclosure provide an apparatus including: a phase detector for detecting a write frequency of a deserializer and a read frequency of a serializer, such that the phase detector outputs a first code sequence in response to the write frequency being greater than the read frequency, or a second code sequence at the rotator input in response to the write frequency being less than the read frequency; and a phase rotator for receiving the first code sequence or the second code sequence from the phase rotator to transmit a pacing signal having the read frequency to the deserializer, wherein the pacing signal causes the read frequency to increase or decrease based on whether the read frequency is different from the write frequency.

A data transmission device of an embodiment includes a buffer, a first determination circuit, a first flip-flop, a second flip-flop, and a second determination circuit. The buffer holds input data of a predetermined bit width. The first determination circuit determines whether or not the input data is held in the buffer. The first flip-flop receives output of the first determination circuit as input and operates at one of a rising edge and a falling edge of a second clock signal which is asynchronous with the first clock signal. The second flip-flop receives output of the first flip-flop as input and operates at another of the rising edge and the falling edge of the second clock signal. The second determination circuit determines an error based on a request signal which is synchronized with the second clock signal and output of the second flip-flop.

A radio receiver device comprises an analogue-to-digital converter clocked by a first clock signal which receives a radio signal. A digital circuit portion receives a digital signal produced by the analogue-to-digital converter and comprises digital processing units clocked by a second clock derived from the first clock and which produce an output signal at an output sample rate. A counter clocked by the second clock counts samples at the output sample rate. A network timer clocked by a reference of a network clock produces a receiver enable flag synchronised to the first clock. The counter is enabled when the flag is set and sets a trigger flag when the count exceeds a predetermined threshold. A buffer receives the output signal and is enabled when the trigger flag is set.

Interface devices and systems that include interface devices are disclosed. In some implementations, a device includes a transceiver configured to transmit and receive data, a lane margining controller in communication with the transceiver and configured to control the transceiver to transmit, through a margin command, to an external device, a request for requesting a state of an elastic buffer of the external device, and control the transceiver to receive the state of the elastic buffer of from the external device, and a port setting controller adjust a clock frequency range of a spread spectrum clocking scheme based on the state of the elastic buffer.