The present application is directed to signal delay control and related apparatuses, systems, and methods. An apparatus includes delay elements and control circuitry electrically connected to the delay elements. The delay elements are configured to receive skewed data signals and delay codes indicating delay quantities. The delay elements are also configured to provide delayed data signals delayed relative to the skewed data signals by the delay quantities. The control circuitry is configured to provide the delay codes, which are selected to reduce a timing skew of the delayed data signals relative to a timing skew of the skewed data signals. A system includes a first device, a second device including the apparatus, and transmission lines electrically connected between the first device and the second device. A method includes calibrating the delay codes.

The present application is directed to signal delay control and related apparatuses, systems, and methods. An apparatus includes delay elements and control circuitry electrically connected to the delay elements. The delay elements are configured to receive skewed data signals and delay codes indicating delay quantities. The delay elements are also configured to provide delayed data signals delayed relative to the skewed data signals by the delay quantities. The control circuitry is configured to provide the delay codes, which are selected to reduce a timing skew of the delayed data signals relative to a timing skew of the skewed data signals. A system includes a first device, a second device including the apparatus, and transmission lines electrically connected between the first device and the second device. A method includes calibrating the delay codes.

A network transceiver device is provided, including at least two variable gain amplifiers (VGAs), and at least two sets of analog digital converters (ADCs), each set including ADCs coupled to an output of one of the VGAs, the sets being arranged in VGA-specific channels. The device includes a plurality of feed-forward equalizers (FFEs), each FFE being coupled to receive an output of one of the ADCs in one of the VGA-specific channels. Each FFE is configured to adaptively equalize the output received from the ADCs utilizing a first equalization coefficient subset with coefficient values that are common to all FFEs, and a second equalization coefficient subset that is channel specific and that has a first set of coefficient values for a first VGA-specific channel and a second set of coefficient values for a second VGA-specific channel, the sets of coefficient values being computed independently.

A physical layer transceiver for a serial data channel includes receiver circuitry having a local clock. Received signals arrive on the channel according to a remote clock. Clock-data recovery circuitry aligns the local clock with the remote clock by correcting phase and frequency error between the local and remote clocks. The clock-data recovery circuitry includes digital phase error detection circuitry operating according to a digital clock to detect phase error between the local and remote clocks, analog phase rotation circuitry to correct the detected phase error, distribution circuitry to divide the detected phase error into multiple phase error steps, and an analog clock source configured to provide the local clock to the analog phase rotation circuitry, and to provide to the distribution circuitry a distribution clock that is slower than the local clock, to correct the local clock by at least one step during one digital clock period.

A physical layer transceiver for a serial data channel includes receiver circuitry having a local clock. Received signals arrive on the channel according to a remote clock. Clock-data recovery circuitry aligns the local clock with the remote clock by correcting phase and frequency error between the local and remote clocks. The clock-data recovery circuitry includes digital phase error detection circuitry operating according to a digital clock to detect phase error between the local and remote clocks, analog phase rotation circuitry to correct the detected phase error, distribution circuitry to divide the detected phase error into multiple phase error steps, and an analog clock source configured to provide the local clock to the analog phase rotation circuitry, and to provide to the distribution circuitry a distribution clock that is slower than the local clock, to correct the local clock by at least one step during one digital clock period.

A phase calibration method includes sweeping phase codes applicable to a serial clock signal, identifying a first, a second, a third, and a fourth phase code, wherein the first phase code causes zero plus a first threshold number of bits extracted from the serial data signal to be a particular value, wherein the second phase code causes all minus a second threshold number of bits extracted from the serial data signal to be the particular value, wherein the third phase code causes all minus a third threshold number of bits extracted from the serial data signal to be the particular value, wherein the fourth phase code causes zero plus a fourth threshold number of bits extracted from the serial data signal to be the particular value, determining an average phase code based on the identified phase codes.

A phase calibration method includes sweeping phase codes applicable to a serial clock signal, identifying a first, a second, a third, and a fourth phase code, wherein the first phase code causes zero plus a first threshold number of bits extracted from the serial data signal to be a particular value, wherein the second phase code causes all minus a second threshold number of bits extracted from the serial data signal to be the particular value, wherein the third phase code causes all minus a third threshold number of bits extracted from the serial data signal to be the particular value, wherein the fourth phase code causes zero plus a fourth threshold number of bits extracted from the serial data signal to be the particular value, determining an average phase code based on the identified phase codes.

A first physical layer device includes a first transmitter and a first receiver. The first transmitter transmits first data to a second physical layer device over a medium at a first line rate during a first transmit period. The first receiver is configured to not receive data during the first transmit period and an echo reflection period occurring after the first transmit period. The echo reflection period is based on a length of the medium between the first physical layer device and the second physical layer device. The first receiver is configured to, after the echo reflection period, receive second data from the second physical layer device over the medium at a second line rate that is less than the first line rate.

A first physical layer device includes a first transmitter and a first receiver. The first transmitter transmits first data to a second physical layer device over a medium at a first line rate during a first transmit period. The first receiver is configured to not receive data during the first transmit period and an echo reflection period occurring after the first transmit period. The echo reflection period is based on a length of the medium between the first physical layer device and the second physical layer device. The first receiver is configured to, after the echo reflection period, receive second data from the second physical layer device over the medium at a second line rate that is less than the first line rate.

The present disclosure relates to a data driving device and a method of driving the data driving device and, more particularly, to a data driving device and a method of driving the same in which a tuning of a set value of an internal circuit is automatically performed.