A sample-and-hold amplification circuit can include a sampling circuit configured to sample first and second input signals in response to first and second control signals to generate first and second sampled signals, an amplification circuit configured to amplify a voltage difference between the first and second sampled signals to generate first and second output signals, and an offset compensation circuit configured to form a first path between input and output terminals of the amplification circuit in response to the first control signal to store an offset of the input terminal and form a second path between the input and output terminals in response to the second control signal to reflect the offset to the output terminal.

Methods, systems, and devices for low voltage ferroelectric memory cell sensing are described. As part of an access operation for a memory cell, gates of two cascodes may be biased to compensate for associated threshold voltages. An extracted signal corresponding to a charge stored in the memory cell may be transferred through a first cascode to charge a first capacitor. Similarly, a reference signal developed at a dummy digit line may be transferred through a second cascode to charge a second capacitor. By comparing the reference signal developed at the dummy digit line to the extracted signal from the memory cell, the effect of variations in memory cell performance on the sense window may be reduced. Additionally, based on biasing the gates of the cascodes, the difference between the signals compared at the sense component may be low compared to other sensing schemes.

Embodiments provide a data sampling circuit and a data sampling device. The sampling circuit includes: a first sampling module configured to respond to a signal from a data signal terminal and a signal from a reference signal terminal and to act on a first node and a second node; a second sampling module configured to respond to a signal from the first node and a signal from the second node and to act on a third node and a fourth node; a latch module configured to input a high level signal to a first output terminal and input a low level signal to a second output terminal or input the low level signal to the first output terminal and input the high level signal to the second output terminal according to a signal from the third node and a signal from the fourth node; and a decision feedback equalization module.

A comparator may include: a comparison block suitable for comparing a ramp signal and a pixel signal, and outputting a comparison signal; a voltage adjusting block suitable for adjusting a clamping voltage; and an output voltage swing control block suitable for controlling an output voltage swing of the comparison block according to the clamping voltage from the voltage adjusting block.

A sample holding circuit includes a signal input terminal, a first sampling unit, a second sampling unit, and a holding unit. The signal input terminal receives a first reference voltage or a second reference voltage, the first sampling unit samples the first reference voltage when a first clock signal is triggered to obtain a first sampling voltage, the second sampling unit samples the second reference voltage when a second clock signal is triggered to obtain a second sampling voltage. The holding unit receives the first sampling voltage and the second sampling voltage when a third clock signal is triggered. The sample holding circuit effectively simplifies circuit structure and reduces the use of amplifiers, also improving the signal to noise ratio.

The present disclosure provides a comparator and a decision feedback equalization circuit. The comparator includes: a first sampling circuit provided with an output terminal, and configured to generate, under the control of a first control signal and a clock signal, a first differential signal according to a signal to be compared and a first reference signal; a second sampling circuit provided with an output terminal connected to the output terminal of the first sampling circuit, and configured to generate, under the control of a second control signal and the clock signal, a second differential signal according to the signal to be compared and a second reference signal, where the first reference signal is larger than the second reference signal.

The present disclosure relates to a bootstrapped switch circuit, a track-and-hold circuit, an analog-to-digital converter, a method for operating a track-and-hold circuit, a base station, and a mobile station. The bootstrapped switch circuit comprises an output for an output signal, a first input, a switching element configured to couple the output with a signal from the first input, a bootstrapper capacitor configured to drive the switching element, and a second input coupled to the bootstrapper capacitor.

A resistor-capacitor (RC) sensor circuit includes an integration capacitor configured to integrate a representative copy of a current that drives an electronic circuit line. The integration capacitor is configured to integrate over a first time period to generate a first representative voltage and over a second time period to generate a second representative voltage. The RC sensor circuit includes a sampling circuit coupled to the integration capacitor and configured to sample the first representative voltage and the second representative voltage. A ratio of the first sampled voltage and the second sampled voltage is indicative of an RC time constant of the electronic circuit line.

Various embodiments provide for a data sampler with one or more capacitive digital-to-analog converters (DACs) for adjusting a threshold voltage range of the data sampler. According to some embodiments, two or more capacitive DACs can be used to set a threshold voltage for a data sampler and, by doing so, serve as a trigger mechanism for the data sampler.

Bias adjusting circuits (1_(2k-1), 1_2k) (where k is an integer equal to or greater than 1 and equal to or less than N, and N is an integer equal to or more than .sub.2) adjust DC bias voltage of at least one of clock signals such that a duty ratio, which is a ratio between a period in which a clock signal is High as to a clock signal and a period in which the clock signal is Low thereasto, becomes (2N-2k+1):(2k-1). Sampling circuits switch between a track mode in which an output signal tracks an input signal, and a hold mode in which a value of the input signal at a timing of switching from the track mode to the hold mode is held and output, in accordance with clock signals output from the bias adjusting circuits (2_1 to 2_2N).