A serial receiver combines continuous-time equalization, analog interleaving, and discrete-time gain for rapid, efficient data reception and quantization of a serial, continuous-time signal. A continuous-time equalizer equalizes a received signal. A number N of time-interleaved analog samplers sample the equalized continuous-time signal to provide N streams of analog samples transitioning at rate reduced by 1/N relative to the received signal. A set of N discrete-time variable-gain amplifiers amplify respective streams of analog samples. A quantizer then quantizes the amplified streams of analog samples to produce a digital signal.

An apparatus includes a first half-cell, a second half-cell, a multiplexer and a decision feedback equalizer. The first input stage may be configured to present a first differential input to the first auto-zero stage and the second auto-zero stage. The second input stage may be configured to present a second differential input to the third auto-zero stage and the fourth auto-zero stage. The multiplexer may be configured to receive a first output from the first auto-zero stage, receive a second output from the third auto-zero stage and present a decision feedback input comprising one of the first output and the second output. The decision feedback equalizer may be configured to generate a feedback signal in response to the decision feedback input and present the feedback signal to the first feedback buffer and the second feedback buffer.

Technologies for cooperative link equalization include a network device with a network interface controller (NIC). The NIC is to monitor variation in a property of a link channel that connects the network device with a target network device. The NIC detects, based on the channel variation, an event that triggers a condition to change an equalization setting of the link channel. In response to the detection, the NIC communicates, via an in-band equalization control channel, changes to the equalization setting of the link channel to the target network device.

The present invention is directed to electrical circuits. More specifically, embodiments of the presentation provide a CTLE module that includes a two compensation sections. A high-frequency zero RC section is in the source of the differential pair and close to the bias current source. A low-frequency zero section is coupled to an output terminal and configured outside the input signal path. A DC gain tuning section is coupled to the low-frequency zero section. There are other embodiments as well.

An equalizer circuit may include an equalizer controller and a plurality of equalizers. The equalizer controller may prove separate sets of enable signals, delay control signals and voltage control signals to the separate equalizers based on a control signal. The equalizers provide equalizer signals to separate connection nodes between separate pairs of logic circuits. An equalizer may be selectively activated based on a received enable signal. An equalizer may include a delay control circuit and a voltage control circuit. The delay control circuit may delay a received transfer signal to generate a delayed transfer signal based on a received delay control signal. The voltage control circuit may generate an equalizer signal based on the delayed transfer signal and a received voltage control signal. The equalizer circuit may reduce inter-symbol interference in the integrated circuit based on providing the equalizer signals to the connection nodes between the logic circuits.

The present invention is directed to electrical circuits. More specifically, embodiments of the presentation provide a CTLE module that includes a two compensation sections. A high-frequency zero RC section is in the source of the differential pair and close to the bias current source. A low-frequency zero section is coupled to an output terminal and configured outside the input signal path. A DC gain tuning section is coupled to the low-frequency zero section. There are other embodiments as well.

The present invention is directed to electrical circuits. More specifically, embodiments of the presentation provide a CTLE module that includes a two compensation sections. A high-frequency zero RC section is in the source of the differential pair and close to the bias current source. A low-frequency zero section is coupled to an output terminal and configured outside the input signal path. A DC gain tuning section is coupled to the low-frequency zero section. There are other embodiments as well.

A decision feedback equalizer (DFE) includes a sampler for receiving a first input signal and comparing an amplitude of the first input signal with a first predetermined voltage level and a second predetermined voltage level. The DFE includes a DFE logic circuit for receiving at least one first sign signal based on comparison results, and for selectively updating a tap coefficient based on the at least one first sign signal. The DFE logic circuit is configured to update the tap coefficient when the at least one first sign signal indicates the amplitude of the first input signal is not between the first predetermined voltage level and the second predetermined voltage level. The DFE logic circuit is configured to maintain the tap coefficient when the at least one first sign signal indicates the amplitude of the first input signal is between the first and the second predetermined voltage levels.

An equalizer circuit may include an equalizer controller and a plurality of equalizers. The equalizer controller may prove separate sets of enable signals, delay control signals and voltage control signals to the separate equalizers based on a control signal. The equalizers provide equalizer signals to separate connection nodes between separate pairs of logic circuits. An equalizer may be selectively activated based on a received enable signal. An equalizer may include a delay control circuit and a voltage control circuit. The delay control circuit may delay a received transfer signal to generate a delayed transfer signal based on a received delay control signal. The voltage control circuit may generate an equalizer signal based on the delayed transfer signal and a received voltage control signal. The equalizer circuit may reduce inter-symbol interference in the integrated circuit based on providing the equalizer signals to the connection nodes between the logic circuits.