A delta-sigma modulator generates a bit stream signal from an analog signal by operating according to a modulation period including a sampling period and a filtering period and includes a digital-to-analog converter (DAC) configured to generate a charge signal according to one of a first reference voltage and a second reference voltage according to the bit stream signal during the sampling period and to output a signal generated according to the charge signal and the other of the first reference voltage and the second reference voltage; a loop filter configured to charge a sampling signal corresponding to the analog signal during the sampling period and to filter an output from the DAC and a signal generated according to the sampling signal during the filtering period; and a quantizer configured to generate the bit stream signal according to an output from the loop filter in the modulation period.

A delta-sigma modulator includes a first combining circuit, a loop filter circuit, a quantizer circuit, a truncator circuit, a first digital-to-analog converter (DAC) circuit, and a compensation circuit. The first combining circuit generates a first analog signal by combining an analog feedback signal and an analog input signal. The loop filter circuit generates a loop-filtered signal according to the first analog signal. The quantizer circuit outputs a first digital signal that is indicative of a digital combination result of at least a truncation error compensation signal and the loop-filtered signal. The truncator circuit performs truncation upon the first digital signal to generate a second digital signal. The first DAC circuit generates the analog feedback signal according to the second digital signal. The compensation circuit generates the truncation error compensation signal according to a truncation error resulting from truncation performed upon the first digital signal.

A correction method and a correction circuit for a sigma-delta modulator (SDM) are provided. The SDM includes a loop filter, a quantizer, and a digital-to-analog converter (DAC). The correction method includes the following steps: controlling the DAC not to receive the output of the quantizer; controlling the SDM to stop receiving signals; inputting a test signal to the DAC; converting the output of the loop filter to a digital signal; comparing the digital signal with a preset value; and adjusting the loop filter according to the result of comparing the digital signal and the preset value.

A second-order modulator includes a plurality of integrators and a parallel higher-bit processing part, and the parallel higher-bit processing part includes a plurality of addition and determination processing sections. The addition and determination processing section receives first and second carry inputs and first and second state inputs, and outputs a quantized output and first and second state outputs. A first selector selects one set from sets of the first and the second state outputs from the plurality of addition and determination processing sections and outputs the selected set, and a second selector selects one quantized output from the quantized outputs from the plurality of addition and determination processing sections. An output of the first selector is used as a selection control signal for the first and the second selectors.

A frequency divider includes a set of frequency-dividing units coupled in series in a sequential order, with the sequence of frequency-dividing units including a lowest unit and a highest unit, with the remaining units being disposed in series between the lowest unit and the highest unit. The lowest unit is coupled to receive an input clock whose frequency is to be divided and provided as an output clock. Each frequency-dividing unit in the set is coupled to receive a corresponding first clock as an input and is operable to generate a corresponding second clock as an output. The frequency divider includes a logic block to generate a first set of edges of the output clock synchronous with the input clock. The logic block is designed to generate a second set of edges of the output clock synchronous with the output clock of a highest operative frequency-dividing unit in the set.

An instrument configured to process signal data is disclosed. The instrument is operable to control and or change the sampling rate of the signal data from a first sample rate to a second sample rate different than the first sample rate.

A correction method and a correction circuit for a sigma-delta modulator (SDM) are provided. The SDM includes a loop filter, a quantizer, and a digital-to-analog converter (DAC). The correction method includes: generating a test signal for a frequency to be tested; inputting the test signal to a feedforward circuit that includes at least one adjustable impedance circuit, the test signal being inputted to the SDM through the impedance circuit; calculating an output signal of the SDM to obtain a value of a signal transfer function (STF) of the SDM at the frequency to be tested; and adjusting the impedance circuit.

A correction method and a correction circuit for a sigma-delta modulator (SDM) are provided. The SDM includes a loop filter, a quantizer, and a digital-to-analog converter (DAC). The correction method includes: generating a test signal for a frequency to be tested; inputting the test signal to a feedforward circuit that includes at least one adjustable impedance circuit, the test signal being inputted to the SDM through the impedance circuit; calculating an output signal of the SDM to obtain a value of a signal transfer function (STF) of the SDM at the frequency to be tested; and adjusting the impedance circuit.

A correction method and a correction circuit for a sigma-delta modulator (SDM) are provided. The SDM includes a loop filter, a quantizer, and a digital-to-analog converter (DAC). The correction method includes the following steps: controlling the DAC not to receive the output of the quantizer; controlling the SDM to stop receiving signals; inputting a test signal to the DAC; converting the output of the loop filter to a digital signal; comparing the digital signal with a preset value; and adjusting the loop filter according to the result of comparing the digital signal and the preset value.

A frequency divider includes a set of frequency-dividing units coupled in series in a sequential order, with the sequence of frequency-dividing units including a lowest unit and a highest unit, with the remaining units being disposed in series between the lowest unit and the highest unit. The lowest unit is coupled to receive an input clock whose frequency is to be divided and provided as an output clock. Each frequency-dividing unit in the set is coupled to receive a corresponding first clock as an input and is operable to generate a corresponding second clock as an output. The frequency divider includes a logic block to generate a first set of edges of the output clock synchronous with the input clock. The logic block is designed to generate a second set of edges of the output clock synchronous with the output clock of a highest operative frequency-dividing unit in the set.