A receiver receiving a multi-level signal includes a sample and hold circuit, first and second analog-to-digital converting circuits, and a digital-to-analog converting circuit. The sample and hold circuit generates a sample data signal by sampling and holding an input data signal. The first analog-to-digital converting circuit generates a first bit of output data based on the input data signal and a first selection reference voltage among a plurality of reference voltages. The digital-to-analog converting circuit selects at least one additional selection reference voltage from among the plurality of reference voltages based on the first bit of the output data. The second analog-to-digital converting circuit generates at least one additional bit of the output data based on the sample data signal and the at least one additional selection reference voltage.

Provided is a method and an apparatus for optimizing memory power and provide a method and an apparatus for optimizing memory power by minimizing power consumed by pins of a memory by using an SBR pattern. The method of optimizing memory power using a PAM-4 (Pulse-Amplitude Modulation-4) method includes: setting a ratio and sizes of a pull-up transistor and a pull-down transistor included in a driver according to a smallest size of a plurality of eyes included in an eye diagram of a memory; and setting a reference voltage of a sampler and a phase interpolator (PI) digital code value included in the memory by using a signal bit response (SBR) pattern.

A device and method for a receiver configured to perform timing recovery decoupled feed-forward equalizer (FFE) adaptation. The receiver device can include an analog front-end (AFE) device, which is coupled to a time-interleaved (TI) interface. The TI interface is coupled in a timing recovery feedback loop to FFE equalizers, a digital signal processor (DSP), a delay timing loop (DTL) device, and a clock device, which feeds back to the TI interface. The DSP has an additional pathway to the FFE equalizers, which has an additional pathway to the DTL device. The DTL loop is equipped with an interleave specific enable/disable vector Q[1:N] that can turn on/off the contribution of the specific time interleave errors to the timing recovery loop, which allows the FFE adaptation process to be decoupled from the timing recovery loop.

Embodiments are disclosed for facilitating an end-to-end link channel with one or more lookup tables for equalization. An example system includes a first transceiver and a second transceiver. The first transceiver includes a clock data recovery (CDR) circuit configured to receive communication data from a switch and to manage a lookup table associated with equalization of the communication data. The first transceiver also includes a first driver circuit communicatively coupled to the CDR circuit and configured to generate an electrical signal associated with the communication data. The second transceiver includes a second driver circuit, communicatively coupled to the first transceiver, that is configured to receive the electrical signal from the first transceiver and to modulate a laser source based on the electrical signal to generate an optical signal via the laser source.

Provided are a memory device and a memory system including the same. The memory device may include a data bus inversion (DBI) mode selector configured to select a first multi-bit DBI signal from among a plurality of multi-bit DBI signals respectively corresponding to a plurality of DBI modes according to multi-bit data; a multi-mode DBI encoder configured to generate encoded multi-bit data by DBI encoding the multi-bit data according to the first multi-bit DBI signal; and a transceiver configured to transmit a data symbol corresponding to the encoded multi-bit data through a data channel and transmit a DBI symbol corresponding to the first multi-bit DBI signal through a DBI channel.

Some examples described herein provide an integrated circuit comprising an auxiliary clock and data recovery (CDR) circuitry. The CDR circuitry is configured to oversample an incoming data signal and generate a locked clock signal. The auxiliary CDR circuitry may comprise a phase-locked loop (PLL) configured to receive the incoming data signal and generate the locked clock signal. The PLL may comprise a phase detector (PD) configured to receive the incoming data signal and capture a number of samples of the incoming data signal in response to a number of adjacent clock signals and minimum data transition thresholds implemented by an intersymbol interference (ISI) filter, the minimum data transition thresholds identifying minimum data transitions in the incoming data signal.

The present disclosure provides a method for estimating a frequency offset, including: extracting sampling points from an input signal according to preset intervals to obtain a plurality of groups of sampling points, with the preset intervals of the groups of sampling points being different; performing processes on a current sampling point and the groups of sampling points to obtain data of arguments of complex numbers corresponding to the preset intervals; and determining an estimation value of a frequency offset of a current input signal according to the data of arguments of complex numbers corresponding to the preset intervals. The present disclosure further provides an apparatus for estimating a frequency offset, an electronic device and a computer-readable medium.

Methods, systems, and devices for replacement scheme for a pulse amplitude modulated bus are described. A device may receive a signal indicative of a set of data associated with a multi-level modulation scheme that includes three or more levels. The device may determine, based on the signal, a first quantity of symbols corresponding to a first level of the multi-level modulation scheme and a second quantity of symbols corresponding to a second level of the multi-level modulation scheme. And the device may modify the signal, based on a sum of the first quantity and the second quantity satisfying a threshold, to replace one or more of the symbols corresponding to the first level with a respective symbol corresponding to a third level of the multi-level modulation scheme.

The present invention enables an apparatus or the like, which does not respond to a communication using a superposed signal, to be used in a system using the superposed signal. This control program, which is for a terminal device connectable to a signal processing device through a communication cable, includes: first identification information acquisition steps for acquiring, from the signal processing device, first identification information for identifying the signal processing device in the terminal device; second identification information acquisition steps for acquiring, through an input part of the terminal device, second identification information for identifying an electric apparatus that is electrically connected to the signal processing device and operates an operation element; generation steps for generating association information for associating the first identification information with the second identification information; and output steps for outputting the association information so that the association information is received by the information processing device.

An illustrative receiver includes: a decision element that derives symbol decisions from a slicer input signal; an equalizer that converts a receive signal into the slicer input signal; a summer that combines the symbol decisions with the slicer input signal to produce an error signal; and a level finder that operates on said signals to determine thresholds at which each signal has a given probability of exceeding the threshold. One illustrative level finder circuit includes: a gated comparator and an asymmetric accumulator. The gated comparator asserts a first or a second gated output signal to indicate when an input signal exceeds or falls below a threshold with a programmable condition being met. The asymmetric accumulator adapts the threshold using up steps for assertions of the first gated output signal and down steps for assertions of the second gated output signal, with the up-step size being different than the down-step size.