The present disclosure relates to an in-vehicle communication device and a time synchronization method thereof. The in-vehicle communication device includes a clock generator for generating a clock signal, a local counter for counting the number of pulses of the clock signal, a transceiver for receiving a message via an in-vehicle communication network, and a processor that determines whether the message received via the transceiver is a synchronization message, extracts synchronization time information from the synchronization message, and adjusts a count value of the local counter based on the synchronization time information to perform time synchronization.

Disclosed embodiments relate, generally, to improved data reception handling at a physical layer. Some embodiments relate to end of line systems that include legacy media access control (MAC) devices and PHY devices that implement improved data reception handling disclosed herein. The improved data reception handling improves the operation of legacy systems, and the MAC more specifically, and in some cases to comply with media access tuning protocols implemented at the physical layer.

Aspects of the invention include a process for receiving data and a first clock signal of a first chip and a second clock signal of a second chip, the data being received on a data path and the first clock signal being received on a clock signal path, and determining that the first clock signal is arriving before the second clock signal by a difference quantity. Also, the process includes adding delay to the data path and the clock signal path according to the difference quantity.

Certain examples described herein provide a method for providing a collaborative session over a network. In these examples, a collaborative session is a series of geographically-separated temporally-coordinated events, such as a performance or concert. In examples, a global latency is set for the collaborative session. The global latency is set to a value greater than a longest latency for a plurality of client devices engaging in the collaborative session, and is defined as a function of a temporal rate for the series of temporally-coordinated events. During the collaborative session data streams are received from the plurality of client devices and presentation of the received data streams on the plurality of client devices is synchronised to enforce the global latency.

A transmitter circuit includes a phase locked loop circuit, having one or more operational characteristics indicative of an operating state of the phase locked loop circuit. The phase locked loop circuit is configured to generate a frequency signal. The transmitter circuit also includes a power amplifier configured to selectively drive an antenna with a drive signal according to the frequency signal, and a programmable delay circuit configured to controllably extend a propagation delay between the frequency signal and the drive signal of the power amplifier. The programmable delay circuit is programmed such that a first value of a particular operational characteristic of the phase locked loop circuit is substantially equal to a second value of the operational characteristic of the phase locked loop circuit. The first value is measured with the power amplifier not driving the antenna. The second value is measured with the power amplifier driving the antenna.

The present invention relates to an adaptive synchronization device for demodulating a signal in linear modulation (x). The device functions from a sampled version of the signal (x). The device being characterized in that it comprises: at least one synchronization module (F) comprising: at least one first sub-module (F.sub.n) arranged to deliver a first output signal (y) from the input signal (x) received at a period (T) less than the value (I) with (B) the bandwidth of the input signal (x); this first sub-module (F.sub.n) is capable of compensating a transmission delay of the input signal (x) by estimation of the propagation delay () between a transmitter and a receiver of a transmission medium; this first sub-module adapts the rate at its output to one sample per symbol; at least one second sub-module (F.sub.u) arranged to deliver a corrective () to be applied to the current estimation of the delay (), from an error term (w) defining the decision error of the device and the influence of the processings downstream of the first sub-module (F); at least one correction module of transmission imperfections (H), disposed downstream of the synchronization module (F) and forming a correction chain of transmission imperfections of the first output signal (y) received by this module (H) at the rhythm T, and comprising: at least one first sub-module (H.sub.n) arranged to deliver a second output signal (z) at the rhythm (T) estimating a stream of emitted symbols (ai); at least one second sub-module (H.sub.p) configured to deliver the error term (w), by application of a correction to an error term (v) for estimation of symbols to consider the influence of the processings included in the first sub-module (H.sub.n). $\begin{array}{cc}\left(\frac{1}{B}\right)& \left(I\right)\end{array}$

An electronic device includes processing circuitry outputting first to third signals, delaying first to third signals to output fourth to sixth signals, generating a pulse signal based on the fourth signal, the fifth signal, and the sixth signal, detecting lengths of intervals, and adjusting at least one of a first code, a second code, and a third code based on fourth codes.

A method is provided for synchronizing a source device with a sink device. The source device transmits a stream of packets to the sink device. The source device receives feedback from the sink device indicating packet arrival times of the packets at the sink device. Based on the feedback, in some aspects, the source device determines an average time shift in the packet arrival times at the sink device, wherein the average time shift is relative to expected packet arrival times of the packets at the sink device. In some such aspects, the source device detects that the average time shift exceeds a threshold, and in response to the detecting, adjusts a streaming time of the stream of packets to synchronize, within a predefined tolerance, the source device with the sink device.

Systems, apparatuses, and methods for utilizing training sequences on a replica lane are described. A transmitter is coupled to a receiver via a communication channel with a plurality of lanes. One of the lanes is a replica lane used for tracking the drift in the optimal sampling point due to temperature variations, power supply variations, or other factors. While data is sent on the data lanes, test patterns are sent on the replica lane to determine if the optimal sampling point for the replica lane has drifted since a previous test. If the optimal sampling point has drifted for the replica lane, adjustments are made to the sampling point of the replica lane and to the sampling points of the data lanes.

A communications system including a transmitter having a modulator that converts information bits to samples, a transmitter pseudo random number generator that generates a sequence of transmitter random numbers defining a time dilation function, and a transmitter time varying delay processor responsive to the samples and the time dilation function, where the transmitter time varying delay processor dithers the samples in time based on the time dilation function. The system also includes a receiver responsive to the dithered samples from the transmitter, where the receiver includes a receiver pseudo random number generator that generates a sequence of receiver random numbers in sync with the transmitter random numbers, a receiver time varying delay processor responsive to the receiver random numbers and the dithered samples, where the receiver time varying delay processor removes the dithering of the samples, and a demodulator for demodulating the samples to recover the information bits.