A high-speed interface apparatus and method of correcting skew in the apparatus are provided. A high-speed transmitter includes a transmission D-PHY module that generates and transmits a clock signal through a clock channel, generates a deskew synchronous code and test data in response to a deskew request signal, transmits the deskew synchronous code followed by the test data through a data channel, and transmits a normal synchronous code followed by normal data through the data channel in normal mode.

One exemplary aspect relates to normalizing latency in a networking environment to reduce the chances of creating an unfair advantage. While an exemplary aspect will be discussed in relation to a gaming environment, it is to be appreciated that the techniques disclosed herein can be applied to other environments where latency normalization or the ability to maintain latency between various endpoints is desired. For example, other environments include eSporting, on-line betting, fantasy esports, streaming services, etc. Some more specific examples include World of Warcraft, Overwatch, H1Z1, PUBG, Fortnite, Realm Royale, Planet Side 2, real-time strategy games, slot machines, electronic poker tournaments, etc.

A method including providing a network element including an ingress port, an egress port, and a delay equalizer, providing an equalization message generator, receiving, at the ingress port, a plurality of data packets from multiple sources, each data packet having a source indication and a source-provided time stamp, determining, at the ingress port, a received time stamp for at least some of the received data packets, passing the received data packets, the source-provided time stamps, and the received time stamps to the delay equalizer, the delay equalizer computing, for each source, a delay for synchronizing that source with other sources, the equalization message generator receiving an output, for each source, including the delay for that source, from the delay equalizer and producing a delay message instructing each source regarding the delay for that source, and sending, from the egress port, the delay message to each source. Related apparatus is also provided.

A CAN transceiver includes a first terminal which receives a transmit signal from a CAN microcontroller. A splitter unit transmits a signal derived from the transmit signal to a CAN bus a via bus connection. A unit receives signals from the CAN bus via the bus connection. A second terminal sends a receive signal derived from the received signals to the CAN microcontroller. The transmit and receive signals include a pulsed signal waveform which represents data bits. Delay circuits apply a deliberate delay to the rising or falling edge of pulses of the transmit signal and/or a deliberate delay to the rising or falling edge of pulses of the receive signal.

A method including providing a network element including an ingress port, an egress port, and a delay equalizer, providing an equalization message generator, receiving, at the ingress port, a plurality of data packets from multiple sources, each data packet having a source indication and a source-provided time stamp, determining, at the ingress port, a received time stamp for at least some of the received data packets, passing the received data packets, the source-provided time stamps, and the received time stamps to the delay equalizer, the delay equalizer computing, for each source, a delay for synchronizing that source with other sources, the equalization message generator receiving an output, for each source, including the delay for that source, from the delay equalizer and producing a delay message instructing each source regarding the delay for that source, and sending, from the egress port, the delay message to each source. Related apparatus is also provided.

A method for processing audio signals in a radio transmitter, includes: receiving an analog audio sample stream and a digital audio sample stream; determining offsets in time between the analog audio stream and the digital audio stream using a normalized cross-correlation of audio envelopes of the analog audio sample stream and the digital audio sample stream; filtering the determined offsets in time to produce filtered offset values; determining an alignment slip adjustment value as a function of the filtered offset values; aligning the analog audio sample stream and the digital audio sample stream using the determined alignment slip adjustment value; and generating a hybrid radio signal for broadcast that includes time-aligned analog audio and digital audio.

A signaling system is disclosed. The signaling system includes a first integrated circuit (IC) chip to receive a data signal and a strobe signal. The first IC includes circuitry to sample the data signal at times indicated by the strobe signal to generate phase error information and circuitry to output the phase error information from the first IC device. The system further includes a signaling link and a second IC chip coupled to the first IC chip via the signaling link to output the data signal and the strobe signal to the first IC chip. The second IC chip includes delay circuitry to generate the strobe signal by delaying an aperiodic timing signal for a first time interval and timing control circuitry to receive the phase error information from the first IC chip and adjust the first time interval in accordance with the phase error information.

A code acquisition module for a direct sequence spread spectrum (DSSS) receiver includes: a Sparse Discrete Fourier transform (SDFT) module configured to perform an SDFT on a finite number of non-uniformly distributed frequencies comprising a preamble of a received DSSS frame to calculate Fourier coefficients for the finite number of non-uniformly distributed frequencies; a multiplier configured to multiply the Fourier coefficients for the finite number of non-uniformly distributed frequencies of the received DSSS frame by complex conjugate Fourier coefficients for the finite number of non-uniformly distributed frequencies to generate a cross-correlation of the received DSSS frame and the complex conjugate Fourier coefficients; and a filter module configured to input the cross-correlation and output a delay estimation for the received DSSS frame.

Method for synchronization of a MoCA network including a plurality of MoCA node devices (n.sub.0-n.sub.4) interconnected through a coaxial network. The method includes transmitting a reference signal from a first node device onto the coaxial network. The method further includes receiving a loopback signal from a further node device through the coaxial network, determining a time delay value (d.sub.i,j) based on a time lapse (T.sub.i,j) between transmitting the reference signal and receiving the loopback signal, and sending the time delay value to said further node 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.